A nuclear gene essential for mitochondrial replication suppresses a defect of mitochondrial transcription in Saccharomyces cerevisiae

Yeast Chromatin Mutants Reveal Altered mtDNA Copy Number and Impaired Mitochondrial Membrane Potential

Mitochondria are multifunctional, dynamic organelles important for stress response, cell longevity, ageing and death. Although the mitochondrion has its genome, nuclear-encoded proteins are essential in regulating mitochondria biogenesis, morphology, dynamics and function. Moreover, chromatin structure and epigenetic mechanisms govern the accessibility to DNA and control gene transcription, indirectly influencing nucleo-mitochondrial communications. Thus, they exert crucial functions in maintaining proper chromatin structure, cell morphology, gene expression, stress resistance and ageing. Here, we present our studies on the mtDNA copy number in Saccharomyces cerevisiae chromatin mutants and investigate the mitochondrial membrane potential throughout their lifespan. The mutants are arp4 (with a point mutation in the ARP4 gene, coding for actin-related protein 4-Arp4p), hho1Δ (lacking the HHO1 gene, coding for the linker histone H1), and the double mutant arp4 hho1Δ cells with the two mutations. Our findings showed that the three chromatin mutants acquired strain-specific changes in the mtDNA copy number. Furthermore, we detected the disrupted mitochondrial membrane potential in their chronological lifespan. In addition, the expression of nuclear genes responsible for regulating mitochondria biogenesis and turnover was changed. The most pronounced were the alterations found in the double mutant arp4 hho1Δ strain, which appeared as the only petite colony-forming mutant, unable to grow on respiratory substrates and with partial depletion of the mitochondrial genome. The results suggest that in the studied chromatin mutants, hho1Δ, arp4 and arp4 hho1Δ, the nucleus-mitochondria communication was disrupted, leading to impaired mitochondrial function and premature ageing phenotype in these mutants, especially in the double mutant.

Phylogenetic Reconstruction Shows Independent Evolutionary Origins of Mitochondrial Transcription Factors from an Ancient Family of RNA Methyltransferase Proteins

Here, we generate a robust phylogenetic framework for the rRNA adenine N(6)-methyltransferase (RAMTase) protein family that shows a more ancient and complex evolutionary history within the family than previously reported. RAMTases occur universally by descent across the three domains of life, and typical orthologs within the family perform methylation of the small subunits of ribosomal RNA (rRNA). However, within the RAMTase family, two different groups of mitochondrial transcription factors, mtTFB1 and mtTFB2, have evolved in eukaryotes through neofunctionalization. Previous phylogenetic analyses have suggested that mtTFB1 and mtTFB2 comprise sister clades that arose via gene duplication, which occurred sometime following the endosymbiosis event that produced the mitochondrion. Through dense and taxonomically broad sampling of RAMTase family members especially within bacteria, we found that these eukaryotic mitochondrial transcription factors, mtTFB1 and mtTFB2, have independent origins in phylogenetically distant clades such that their divergence most likely predates the last universal common ancestor of life. The clade of mtTFB2s comprises orthologs in Opisthokonts and the clade of mtTFB1s includes orthologs in Amoebozoa and Metazoa. Thus, we clearly demonstrate that the neofunctionalization producing the transcription factor function evolved twice independently within the RAMTase family. These results are consistent with and help to elucidate outcomes from prior experimental studies, which found that some members of mtTFB1 still perform the ancestral rRNA methylation function, and the results have broader implications for understanding the evolution of new protein functions. Our phylogenetic reconstruction is also in agreement with prior studies showing two independent origins of plastid RAMTases in Viridiplantae and other photosynthetic autotrophs. We believe that this updated phylogeny of RAMTases should provide a robust evolutionary framework for ongoing studies to identify and characterize the functions of these proteins within diverse organisms.

In vitro promoter recognition by the catalytic subunit of plant phage-type RNA polymerases

We identified sequence motifs, which enhance or reduce the ability of the Arabidopsis phage-type RNA polymerases RPOTm (mitochondrial RNAP), RPOTp (plastidial RNAP), and RPOTmp (active in both organelles) to recognize their promoters in vitro with help of a 'specificity loop'. The importance of this data for the evolution and function of the organellar RNA polymerases is discussed. The single-subunit RNA polymerase (RNAP) of bacteriophage T7 is able to perform all steps of transcription without additional transcription factors. Dicotyledonous plants possess three phage-type RNAPs, RPOTm-the mitochondrial RNAP, RPOTp-the plastidial RNAP, and RPOTmp-an RNAP active in both organelles. RPOTm and RPOTp, like the T7 polymerase, are able to recognize promoters, while RPOTmp displays no significant promoter specificity in vitro. To find out which promoter motifs are crucial for recognition by the polymerases we performed in vitro transcription assays with recombinant Arabidopsis RPOTm and RPOTp enzymes. By comparing different truncated and mutagenized promoter constructs, we observed the same minimal promoter sequence supposed to be needed in vivo for transcription initiation. Moreover, we identified elements of core and flanking sequences, which are of critical importance for promoter recognition and activity in vitro. We further intended to reveal why RPOTmp does not efficiently recognize promoters in vitro and if promoter recognition is based on a structurally defined specificity loop of the plant enzymes as described for the yeast and T7 RNAPs. Interestingly, the exchange of only three amino acids within the putative specificity loop of RPOTmp enabled the enzyme for specific promoter transcription in vitro. Thus, also in plant phage-type RNAPs the specificity loop is engaged in promoter recognition. The results are discussed with respect to their relevance for transcription in organello and to the evolution of RPOT enzymes including the divergence of their functions.

The core human mitochondrial transcription initiation complex: It only takes two to tango

We recently demonstrated that the core transcription initiation complex in human mitochondria is a two-component system (POLRMT and h-mtTFB2). Human mtTFA/TFAM, previously proposed to be a requisite initiation complex member, is dispensable for promoter-specific initiation in vitro. We propose that it instead regulates relative promoter activity and/or overall nucleoid transcription and replication potential.

In vivo analysis of mtDNA replication defects in yeast

The yeast Saccharomyces cerevisiae has the capacity to survive large deletions or total loss of mtDNA (petite mutants), and thus in the last few years it has been used as a model system to study defects in mitochondrial DNA (mtDNA) maintenance produced by mutations in genes involved in mtDNA replication. In this paper we describe methods to obtain strains harboring mutations in nuclear genes essential for the integrity of mtDNA, to measure the frequency and the nature of petite mutants, to estimate the point mutation frequency in mtDNA and to determine whether a nuclear mutation is recessive or dominant and, in the latter case, the kind of dominance.

Mitochondrial upstream promoter sequences modulate in vivo the transcription of a gene in yeast mitochondria

An in vivo study of the importance of the length and/or structures of sequences upstream of a mitochondrial promoter was undertaken in Saccharomyces cerevisiae. Short tandem mtDNA repeats were introduced upstream of the COX2 gene. Our data show that its expression is modulated by the sequence located over 200 bp upstream of the promoter. A deletion decreases the level of transcripts to about 50%. The initial level can be recovered by a fill-in AT-rich sequence or partially by the presence of a long repeat tract; on the contrary, a smaller number of copies tends to intensify the effect of the deletion. These results show that the length and base composition upstream of mitochondrial promoter are involved in vivo in the modulation of the gene expression.

Evidence for an early gene duplication event in the evolution of the mitochondrial transcription factor B family and maintenance of rRNA methyltransferase activity in human mtTFB1 and mtTFB2

Most metazoans have two nuclear genes encoding orthologues of the well-characterized Saccharomyces cerevisiae mitochondrial transcription factor B (sc-mtTFB). This class of transcription factors is homologous to the bacterial KsgA family of rRNA methyltransferases, which in Escherichia coli dimethylates adjacent adenine residues in a stem-loop of the 16S rRNA. This posttranscriptional modification is conserved in most metazoan cytoplasmic and mitochondrial rRNAs. Homo sapiens mitochondrial transcription factor B1 (h-mtTFB1) possesses this enzymatic activity, implicating it as a dual-function protein involved in mitochondrial transcription and translation. Here we demonstrate that h-mtTFB2 also has rRNA methyltransferase activity but is a less efficient enzyme than h-mtTFB1. In contrast, sc-mtTFB has no detectable rRNA methyltransferase activity, correlating with the lack of the corresponding modification in the mitochondrial rRNA of budding yeast. Based on these results, and reports that Drosophila melanogaster mtTFB1 and mtTFB2 do not have completely overlapping functions, we propose a model for human mtDNA regulation that takes into account h-mtTFB1 and h-mtTFB2 likely having partially redundant transcription factor and rRNA methyltransferase functions. Finally, phylogenetic analyses of this family of proteins strongly suggest that the presence of two mtTFB homologues in metazoans is the result of a gene duplication event that occurred early in eukaryotic evolution prior to the divergence of fungi and metazoans. This model suggests that, after the gene duplication event, differential selective pressures on the rRNA methyltransferase and transcription factor activities of mtTFB genes occurred, with extreme cases culminating in the loss of one of the paralogous genes in certain species.

Homologs of mitochondrial transcription factor B, sparsely distributed within the eukaryotic radiation, are likely derived from the dimethyladenosine methyltransferase of the mitochondrial endosymbiont

Mitochondrial transcription factor B (mtTFB), an essential component in regulating the expression of mitochondrial DNA-encoded genes in both yeast and humans, is a dimethyladenosine methyltransferase (DMT) that has acquired a secondary role in mitochondrial transcription. So far, mtTFB has only been well studied in Opisthokonta (metazoan animals and fungi). Here we investigate the phylogenetic distribution of mtTFB homologs throughout the domain Eucarya, documenting the first examples of this protein outside of the opisthokonts. Surprisingly, we identified putative mtTFB homologs only in amoebozoan protists and trypanosomatids. Phylogenetic analysis together with conservation of intron positions in amoebozoan and human genes supports the grouping of the putative mtTFB homologs as a distinct clade. Phylogenetic analysis further demonstrates that the mtTFB is most likely derived from the DMT of the mitochondrial endosymbiont.

A Mutation in the Yeast Mitochondrial Core RNA Polymerase, Rpo41, Confers Defects in Both Specificity Factor Interaction and Promoter Utilization

The yeast mitochondrial RNA polymerase (RNAP) is composed of the core RNAP, Rpo41, and the mitochondrial transcription factor, Mtf1. Both are required for mitochondrial transcription, but how the two proteins interact to create a functional, promoter-selective holoenzyme is still unknown. Rpo41 is similar to the single polypeptide bacteriophage T7RNAP, which does not require additional factors for promoter-selective initiation but whose activity is modulated during infection by association with T7 lysozyme. In this study we used the co-crystal structure of T7RNAP and T7 lysozyme as a model to define a potential Mtf1 interaction surface on Rpo41, making site-directed mutations in Rpo41 at positions predicted to reside at the same location as the T7RNAP/T7 lysozyme interface. We identified Rpo41 mutant E1224A as having reduced interactions with Mtf1 in a two-hybrid assay and a temperature-sensitive petite phenotype in vivo. Although the E1224A mutant has full activity in a non-selective in vitro transcription assay, it is temperature-sensitive for selective transcription from linear DNA templates containing the 14S rRNA, COX2, and tRNAcys mitochondrial promoters. The tRNAcys promoter defect can be rescued by template supercoiling but not by addition of a dinucleotide primer. The fact that mutation of Rpo41 results in selective transcription defects indicates that the core RNAP, like T7RNAP, plays an important role in promoter utilization.

Human mitochondrial transcription factor B1 interacts with the C-terminal activation region of h-mtTFA and stimulates transcription independently of its RNA methyltransferase activity

A significant advancement in understanding mitochondrial gene expression is the recent identification of two new human mitochondrial transcription factors, h-mtTFB1 and h-mtTFB2. Both proteins stimulate transcription in collaboration with the high-mobility group box transcription factor, h-mtTFA, and are homologous to rRNA methyltransferases. In fact, the dual-function nature of h-mtTFB1 was recently demonstrated by its ability to methylate a conserved rRNA substrate. Here, we demonstrate that h-mtTFB1 binds h-mtTFA both in HeLa cell mitochondrial extracts and in direct-binding assays via an interaction that requires the C-terminal tail of h-mtTFA, a region necessary for transcriptional activation. In addition, point mutations in conserved methyltransferase motifs of h-mtTFB1 revealed that it stimulates transcription in vitro independently of S-adenosylmethionine binding and rRNA methyltransferase activity. Furthermore, one mutation (G65A) eliminated the ability of h-mtTFB1 to bind DNA yet did not affect transcriptional activation. These results, coupled with the observation that h-mtTFB1 and human mitochondrial RNA (h-mtRNA) polymerase can also be coimmunoprecipitated, lead us to propose a model in which h-mtTFA demarcates mitochondrial promoter locations and where h-mtTFB proteins bridge an interaction between the C-terminal tail of h-mtTFA and mtRNA polymerase to facilitate specific initiation of transcription. Altogether, these data provide important new insight into the mechanism of transcription initiation in human mitochondria and indicate that the dual functions of h-mtTFB1 can be separated.

Transcriptional control of nonfermentative metabolism in the yeast Saccharomyces cerevisiae

Although sugars are clearly the preferred carbon sources of the yeast Saccharomyces cerevisiae, nonfermentable substrates such as ethanol, glycerol, lactate, acetate or oleate can also be used for the generation of energy and cellular biomass. Several regulatory networks of glucose repression (carbon catabolite repression) are involved in the coordinate biosynthesis of enzymes required for the utilization of nonfermentable substrates. Positively and negatively acting complexes of pleiotropic regulatory proteins have been characterized. The Snf1 (Cat1) protein kinase complex, together with its regulatory subunit Snf4 (Cat3) and alternative beta-subunits Sip1, Sip2 or Gal83, plays an outstanding role for the derepression of structural genes which are repressed in the presence of a high glucose concentration. One molecular function of the Snf1 complex is deactivation by phosphorylation of the general glucose repressor Mig1. In addition to regulation of alternative sugar fermentation, Mig1 also influences activators of respiration and gluconeogenesis, although to a lesser extent. Snf1 is also required for conversion of specific regulatory factors into transcriptional activators. This review summarizes regulatory cis-acting elements of structural genes of the nonfermentative metabolism, together with the corresponding DNA-binding proteins (Hap2-5, Rtg1-3, Cat8, Sip4, Adr1, Oaf1, Pip2), and describes the molecular interactions among general regulators and pathway-specific factors. In addition to the influence of the carbon source at the transcriptional level, mechanisms of post-transcriptional control such as glucose-regulated stability of mRNA are also discussed briefly.

Search for protein partners of mitochondrial single-stranded DNA-binding protein Rim1p using a yeast two-hybrid system

RIM1 is a nuclear gene of the yeast Saccharomyces cerevisiae coding for a protein with single-stranded DNA-binding activity that is essential for mitochondrial genome maintenance. No protein partners of Rim1p have been described so far in yeast. To better understand the role of this protein in mitochondrial DNA replication and recombination, a search for protein interactors by the yeast two-hybrid system was performed. This approach led to the identification of several candidates, including a putative transcription factor, Azf1p, and Mph1p, a protein with an RNA helicase domain which is known to influence the mutation rate of nuclear and mitochondrial genomes.

Import of yeast mitochondrial transcription factor (Mtf1p) via a nonconventional pathway

The yeast mitochondrial (mt) transcription factor Mtf1p is imported into the mitochondria from the cytoplasm without a conventional mt-targeting presequence. To understand its import the mt translocation of wild type and mutant Mtf1p constructs was investigated in vitro under various assay conditions. We report here that Mtf1p, unlike most mt matrix proteins hitherto studied, is translocated into the mitochondria independent of membrane potential, ATP hydrolysis, and membrane receptor. This unusual import of Mtf1p was also observed on ice (3 degrees C). Sub-mitochondrial fractionation demonstrated that Mtf1p was translocated in vitro to one or more of the same mt sites as the endogenous protein that includes the matrix. To identify the mt-targeting sequence of Mtf1p, various N-terminal, C-terminal, or internally deleted Mtf1p derivatives were generated. The full-length and C-terminal deletions but not the N-terminal truncated Mtf1p were imported into mitochondria, indicating the importance of its N-terminal sequence for mt targeting. However, the internal deletion of Mtf1p revealed that the first 150-amino acid N-terminal sequence alone was not sufficient for mt targeting of Mtf1p, suggesting that an extended rather than a short N-terminal sequence is required for import. We favor a model in which Mtf1p adopts an import-competent conformation during translation. Consistent with this model are three findings: most of the protein sequence appears to be required for optimal import, urea denaturation eliminates its import competence, and the import-competent form of the protein is more resistant to tryptic hydrolysis than is the denatured protein. This represents a novel mechanism for mitochondrial protein import.

Mutations in the yeast mitochondrial RNA polymerase specificity factor, Mtf1, verify an essential role in promoter utilization

The yeast mitochondrial RNA polymerase (RNAP) is a two-subunit enzyme composed of a catalytic core (Rpo41) and a specificity factor (Mtf1) encoded by nuclear genes. Neither subunit on its own interacts with promoter DNA, but the combined holo-RNAP recognizes and selectively initiates from promoters related to the consensus sequence ATATAAGTA. To pursue the question of why Rpo41, which resembles the single polypeptide RNAPs from bacteriophage T7 and T3, requires a separate specificity factor, we analyzed a collection of Mtf1 point mutations that confer an in vivo petite phenotype. These mutant proteins are able to interact with Rpo41 and are capable of nearly wild type levels of initiation in vitro with a consensus promoter-containing template (14 S rRNA). However, the petite phenotype of two mutants can be explained by the fact that they exhibit dramatic transcriptional defects on non-consensus promoters. Y54F is incapable of transcribing the weak tRNA(Cys) promoter, and C192F cannot transcribe either tRNA(Cys) or the variant COX2 promoter from linear DNA templates. Transcription of the tRNA(Cys) promoter by both mutants was significantly corrected by addition of an initiating dinucleotide primer or by supercoiling the DNA template. These results establish the critical role of Mtf1 in promoter recognition and initiation of transcription.

The C-terminal region of mitochondrial single-subunit RNA polymerases contains species-specific determinants for maintenance of intact mitochondrial genomes

Functional conservation of mitochondrial RNA polymerases was investigated in vivo by heterologous complementation studies in yeast. It turned out that neither the full-length mitochondrial RNA polymerase of Arabidopsis thaliana, nor a set of chimeric fusion constructs from plant and yeast RNA polymerases can substitute for the yeast mitochondrial core enzyme Rpo41p when expressed in Deltarpo41 yeast mutants. Mitochondria from mutant cells, expressing the heterologous mitochondrial RNA polymerases, were devoid of any mitochondrial genomes. One important exception was observed when the carboxyl-terminal domain of Rpo41p was exchanged with its plant counterpart. Although this fusion protein could not restore respiratory function, stable maintenance of mitochondrial petite genomes (rho(-))(-) was supported. A carboxyl-terminally truncated Rpo41p exhibited a comparable activity, in spite of the fact that it was found to be transcriptionally inactive. Finally, we tested the carboxyl-terminal domain for complementation in trans. For this purpose the last 377 amino acid residues of yeast mitochondrial Rpo41p were fused to its mitochondrial import sequence. Coexpression of this fusion protein with C-terminally truncated Rpo41p complemented the Deltarpo41 defect. These data reveal the importance of the carboxyl-terminal extension of Rpo41p for stable maintenance of intact mitochondrial genomes and for distinct species-specific intramolecular protein-protein interactions.

The mitochondrial nucleoid protein, Mgm101p, of Saccharomyces cerevisiae is involved in the maintenance of rho(+) and ori/rep-devoid petite genomes but is not required for hypersuppressive rho(-) mtDNA

The Saccharomyces cerevisiae MGM101 gene encodes a DNA-binding protein targeted to mitochondrial nucleoids. MGM101 is essential for maintenance of a functional rho(+) genome because meiotic segregants, with a disrupted mgm101 allele, cannot undergo more than 10 divisions on glycerol medium. Quantitative analysis of mtDNA copy number in a rho(+) strain carrying a temperature-sensitive allele, mgm101-1, revealed that the amount of mtDNA is halved each cell division upon a shift to the restrictive temperature. These data suggest that mtDNA replication is rapidly blocked in cells lacking MGM101. However, a small proportion of meiotic segregants, disrupted in MGM101, have rho(-) genomes that are stably maintained. Interestingly, all surviving rho(-) mtDNAs contain an ori/rep sequence. Disruption of MGM101 in hypersuppressive (HS) strains does not have a significant effect on the propagation of HS rho(-) mtDNA. However, in petites lacking an ori/rep, disruption of MGM101 leads to either a complete loss or a dramatically decreased stability of mtDNA. This discriminatory effect of MGM101 suggests that replication of rho(+) and ori/rep-devoid rho(-) mtDNAs is carried out by the same process. By contrast, the persistence of ori/rep-containing mtDNA in HS petites lacking MGM101 identifies a distinct replication pathway. The alternative mtDNA replication mechanism provided by ori/rep is independent of mitochondrial RNA polymerase encoded by RPO41 as a HS rho(-) genome is stably maintained in a mgm101, rpo41 double mutant.

A human mitochondrial transcription factor is related to RNA adenine methyltransferases and binds S-adenosylmethionine

A critical step toward understanding mitochondrial genetics and its impact on human disease is to identify and characterize the full complement of nucleus-encoded factors required for mitochondrial gene expression and mitochondrial DNA (mtDNA) replication. Two factors required for transcription initiation from a human mitochondrial promoter are h-mtRNA polymerase and the DNA binding transcription factor, h-mtTFA. However, based on studies in model systems, the existence of a second human mitochondrial transcription factor has been postulated. Here we report the isolation of a cDNA encoding h-mtTFB, the human homolog of Saccharomyces cerevisiae mitochondrial transcription factor B (sc-mtTFB) and the first metazoan member of this class of transcription factors to which a gene has been assigned. Recombinant h-mtTFB is capable of binding mtDNA in a non-sequence-specific fashion and activates transcription from the human mitochondrial light-strand promoter in the presence of h-mtTFA in vitro. Remarkably, h-mtTFB and its fungal homologs are related in primary sequence to a superfamily of N6 adenine RNA methyltransferases. This observation, coupled with the ability of recombinant h-mtTFB to bind S-adenosylmethionine in vitro, suggests that a structural, and perhaps functional, relationship exists between this class of transcription factors and this family of RNA modification enzymes and that h-mtTFB may perform dual functions during mitochondrial gene expression.

Crystal structure of the transcription factor sc-mtTFB offers insights into mitochondrial transcription

Although it is commonly accepted that binding of mitochondrial transcription factor sc-mtTFB to the mitochondrial RNA polymerase is required for specific transcription initiation in Saccharomyces cerevisiae, its precise role has remained undefined. In the present work, the crystal structure of sc-mtTFB has been determined to 2.6 A resolution. The protein consists of two domains, an N-terminal alpha/beta-domain and a smaller domain made up of four alpha-helices. Contrary to previous predictions, sc-mtTFB does not resemble Escherichia coli sigma-factors but rather is structurally homologous to rRNA methyltransferase ErmC'. This suggests that sc-mtTFB functions as an RNA-binding protein, an observation standing in contradiction to the existing model, which proposed a direct interaction of sc-mtTFB with the mitochondrial DNA promoter. Based on the structure, we propose that the promoter specificity region is located on the mitochondrial RNA polymerase and that binding of sc-mtTFB indirectly mediates interaction of the core enzyme with the promoter site.

Single point mutations in either gene encoding the subunits of the heterooctameric yeast phosphofructokinase abolish allosteric inhibition by ATP

Yeast phosphofructokinase is a heterooctameric enzyme subject to a complex allosteric regulation. A mutation in the PFK1 gene, encoding the larger -subunits, rendering the enzyme insensitive to allosteric inhibition by ATP was found to be caused by an exchange of proline 728 for a leucine residue. By in vitro mutagenesis, we introduced this mutation in either PFK1 or PFK2 and found that the exchange in either subunit drastically reduced the sensitivity of the holoenzyme to ATP inhibition. This was accompanied by a lack of allosteric activation by AMP, fructose 2,6-bisphosphate, or ammonium and an increased resistance to heat inactivation. Yeast cells carrying either one mutation or both in conjunction did not display a strong phenotype when grown on fermentable carbon sources and did not show any significant changes in intermediary metabolites. Growth on non-fermentable carbon sources was clearly impaired. The strain carrying both mutant alleles was more sensitive to Congo Red than the wild-type strain or the single mutants indicating differences in cell wall composition. In addition, we found single pfk null mutants to be less viable than wild type at different storage temperatures and a pfk2 null mutant to be temperature-sensitive for growth at 37 degrees C. The latter mutant was shown to be respiration-dependent for growth on glucose.

Mitochondrial protein phosphorylation: lessons from yeasts

The genome of Saccharomyces cerevisiae contains as many as 136 protein kinase encoding genes. However, only a limited number of mitochondrial protein kinases have been characterized. A computer-aided analysis revealed that only seven members of this large protein family are potentially localized in mitochondria. The low abundance of mitochondrially targeted protein kinases in yeast reflects the reductive evolution of mitochondrial signaling components and/or the apparent lack of selection pressure for acquiring mitochondrially localized protein kinases encoded by the host genome. This suggests that mitochondria, like obligatory intracellular bacterial parasites, are no longer dependent on signalling mechanisms mediated by protein kinases residing within the mitochondria. Instead, the nucleo-mitochondrial communication system requiring protein phosphorylation may be predominantly regulated by protein kinases, which are cytosolic and/or anchored to the outer mitochondrial membrane.

Maintenance and integrity of the mitochondrial genome: a plethora of nuclear genes in the budding yeast

Instability of the mitochondrial genome (mtDNA) is a general problem from yeasts to humans. However, its genetic control is not well documented except in the yeast Saccharomyces cerevisiae. From the discovery, 50 years ago, of the petite mutants by Ephrussi and his coworkers, it has been shown that more than 100 nuclear genes directly or indirectly influence the fate of the rho(+) mtDNA. It is not surprising that mutations in genes involved in mtDNA metabolism (replication, repair, and recombination) can cause a complete loss of mtDNA (rho(0) petites) and/or lead to truncated forms (rho(-)) of this genome. However, most loss-of-function mutations which increase yeast mtDNA instability act indirectly: they lie in genes controlling functions as diverse as mitochondrial translation, ATP synthase, iron homeostasis, fatty acid metabolism, mitochondrial morphology, and so on. In a few cases it has been shown that gene overexpression increases the levels of petite mutants. Mutations in other genes are lethal in the absence of a functional mtDNA and thus convert this petite-positive yeast into a petite-negative form: petite cells cannot be recovered in these genetic contexts. Most of the data are explained if one assumes that the maintenance of the rho(+) genome depends on a centromere-like structure dispensable for the maintenance of rho(-) mtDNA and/or the function of mitochondrially encoded ATP synthase subunits, especially ATP6. In fact, the real challenge for the next 50 years will be to assemble the pieces of this puzzle by using yeast and to use complementary models, especially in strict aerobes.

A variant form of the nuclear triiodothyronine receptor c-ErbAalpha1 plays a direct role in regulation of mitochondrial RNA synthesis

In earlier research, we identified a 43-kDa c-ErbAalpha1 protein (p43) in the mitochondrial matrix of rat liver. In the present work, binding experiments indicate that p43 displays an affinity for triiodothyronine (T3) similar to that of the T3 nuclear receptor. Using in organello import experiments, we found that p43 is targeted to the organelle by an unusual process similar to that previously reported for MTF1, a yeast mitochondrial transcription factor. DNA-binding experiments demonstrated that p43 specifically binds to four mitochondrial DNA sequences with a high similarity to nuclear T3 response elements (mt-T3REs). Using in organello transcription experiments, we observed that p43 increases the levels of both precursor and mature mitochondrial transcripts and the ratio of mRNA to rRNA in a T3-dependent manner. These events lead to stimulation of mitochondrial protein synthesis. In transient-transfection assays with reporter genes driven by the mitochondrial D loop or two mt-T3REs located in the D loop, p43 stimulated reporter gene activity only in the presence of T3. All these effects were abolished by deletion of the DNA-binding domain of p43. Finally, p43 overexpression in QM7 cells increased the levels of mitochondrial mRNAs, thus indicating that the in organello influence of p43 was physiologically relevant. These data reveal a novel hormonal pathway functioning within the mitochondrion, involving a truncated form of a nuclear receptor acting as a potent mitochondrial T3-dependent transcription factor.

Stability of the mitochondrial genome requires an amino-terminal domain of yeast mitochondrial RNA polymerase

Mitochondrial RNA (mtRNA) polymerases are related to bacteriophage RNA polymerases, but contain a unique amino-terminal extension of unknown origin and function. In addition to harboring mitochondrial targeting information, we show here that the amino-terminal extension of yeast mtRNA polymerase is required for a mtDNA maintenance function that is separable from the known RNA polymerization activity of the enzyme. Deletion of 185 N-terminal amino acids from the enzyme results in a temperature-sensitive mitochondrial petite phenotype, characterized by increased instability and eventual loss of the mitochondrial genome. Mitochondrial transcription initiation in vivo is largely unaffected by this mutation and expression of just the amino-terminal portion of the protein in trans partially suppresses the mitochondrial defect, indicating that the amino-terminal extension of the enzyme harbors an independent functional domain that is required for mtDNA replication and/or stability. These results suggest that amino-terminal extensions present in mtRNA polymerases comprise functional domains that couple additional activities to the transcription process in mitochondria.

Organellar RNA polymerases of higher plants

The nuclear genome of the model plant Arabidopsis thaliana contains a small gene family consisting of three genes encoding RNA polymerases of the single-subunit bacteriophage type. There is evidence that similar gene families also exist in other plants. Two of these RNA polymerases are putative mitochondrial enzymes, whereas the third one may represent the nuclear-encoded RNA polymerase (NEP) active in plastids. In addition, plastid genes are transcribed from another, entirely different multisubunit eubacterial-type RNA polymerase, the core subunits of which are encoded by plastid genes [plastid-encoded RNA polymerase (PEP)]. This core enzyme is complemented by one of several nuclear-encoded sigma-like factors. The development of photosynthetically active chloroplasts requires both PEP and NEP. Most NEP promoters show certain similarities to mitochondrial promoters in that they include the sequence motif 5'-YRTA-3' near the transcription initiation site. PEP promoters are similar to bacterial promoters of the -10/-35 sigma 70 type.

Mitochondrial involvement in bladder function and dysfunction

Benign bladder pathology resulting from prostatic hypertrophy or other causes is a significant problem associated with ageing in humans. This condition is characterized by increased bladder mass, decreased urinary flow rate, decreased compliance, and these and other changes in bladder function often subject patients to increased risk of urinary tract infection. While the physiologic attributes of benign bladder pathology have been extensively described in humans and in various animal model systems, the biochemical and molecular genetic bases for that pathology have only recently been investigated in detail. Studies demonstrate that mitochondrial energy production and utilization are severely impaired in bladder smooth muscle during benign bladder disease, and to a large extent this realization has provided a rational basis for understanding the characteristic alterations in urinary flow and compliance in bladder tissue. Recent investigations targeting the detailed molecular basis for impaired mitochondrial function in the disease have shown that performance of the organellar genetic system, and to a large extent that of relevant portions of the nuclear genetic system as well, is severely aberrant in bladder tissue. In this article, we discuss the physiologic aspects of benign bladder disease, summarize biochemical evidence for the altered mitochondrial energy metabolism that appears to underlie bladder pathology, review the structure and function of the mitochondrial genetic system, and discuss molecular genetic studies of that system which have begun to provide a mechanistic explanation for the biochemical and physiological abnormalities that characterize the disease. We also discuss areas for further research which will be critically important in increasing our understanding of the detailed causes of benign bladder pathology.

The mitochondrial genome: structure, transcription, translation and replication

Mitochondria play a central role in cellular energy provision. The organelles contain their own genome with a modified genetic code. The mammalian mitochondrial genome is transmitted exclusively through the female germ line. The human mitochondrial DNA (mtDNA) is a double-stranded, circular molecule of 16569 bp and contains 37 genes coding for two rRNAs, 22 tRNAs and 13 polypeptides. The mtDNA-encoded polypeptides are all subunits of enzyme complexes of the oxidative phosphorylation system. Mitochondria are not self-supporting entities but rely heavily for their functions on imported nuclear gene products. The basic mechanisms of mitochondrial gene expression have been solved. Cis-acting mtDNA sequences have been characterised by sequence comparisons, mapping studies and mutation analysis both in vitro and in patients harbouring mtDNA mutations. Characterisation of trans-acting factors has proven more difficult but several key enzymes involved in mtDNA replication, transcription and protein synthesis have now been biochemically identified and some have been cloned. These studies revealed that, although some factors may have an additional function elsewhere in the cell, most are unique to mitochondria. It is expected that cell cultures of patients with mitochondrial diseases will increasingly be used to address fundamental questions about mtDNA expression.

Usage of non-canonical promoter sequence by the yeast mitochondrial RNA polymerase

Prior work has demonstrated that a conserved nonanucleotide [5'-TATAAGTAA(+2)] promoter sequence is used by the mitochondrial [mt]1 RNA polymerase in Saccharomyces cerevisiae. However, the highly AT-rich yeast mt genome carries many other promoter-like sequences, but only a fraction of them are involved in gene-specific transcription. To examine the sequence variability of this nonanucleotide promoter motif, single or multiple nt substitutions were introduced into the canonical promoter sequence. The transcriptional activity of these altered promoter sequences was examined under the in-vitro reaction conditions. The results presented here determined that several variant promoter sequences (i. e. TAAAAGTAA, TATAAGAAA, TATAAGTAG, TATAAGAAG, TATAAGAGA, TATAAGGGA, TATAAGTGG, TAAAAGTAG) were efficiently used by the mtRNA polymerase. However, a single (i.e. AATAAGTAA, TTTAAGTAA, TATTAGTAA, TATAACTAA, TATAAGGAA, TATAAGTAT) or multiple (TATAGGAAA, TAAAAGGAA, TATAGGGAA, TAAAGGAAA, TAAAGGGAA) nt substitution(s) in other locations drastically reduced mt promoter function. Interestingly, some of these poorly or partially active promoter variants (i.e. TATAAGGAA, TATAAGTAT, TATAAGTCA) became fully functional in the presence of sequence-specific dinucleotide primer. Since dinucleotide primer bypasses the first phosphodiester bond formation in transcription, it is suggested that the -1T-->G, +1A-->C and +2A-->T mutations affect mt transcription at the level of initiation rather than polymerase binding.

Precise mapping and characterization of the RNA primers of DNA replication for a yeast hypersuppressive petite by in vitro capping with guanylyltransferase

The active origins of DNA replication for yeast (Saccharomyces cerevisiae) mitochondrial DNA share 280 conserved base pairs and have a promoter. Since intact replication intermediates retain their initiating ribonucleotide triphosphate, we used guanylyltransferase to in vitro cap the replication intermediates present in restriction enzyme-cut DNA from an ori-5 hypersuppressive petite. Restriction mapping and RNA sequencing of these labeled intermediates showed that each DNA strand is primed at a single discrete nucleotide, that one primer starts at the promoter and that the other primer starts 34 nt away, outside the conserved region. Deoxyribonuclease digestion of the capped fragments left resistant RNA primers, which enabled identification of zones of transition from RNA to DNA synthesis. Some of the results contradict the prevailing model for priming at the yeast mitochondrial origins.

Characterization of DNA-Binding Proteins from Pea Mitochondria

We studied transcription initiation in the mitochondria of higher plants, with particular respect to promoter structures. Conserved elements of these promoters have been successfully identified by in vitro transcription systems in different species, whereas the involved protein components are still unknown. Proteins binding to double-stranded oligonucleotides representing different parts of the pea (Pisum sativum) mitochondrial atp9 were analyzed by denaturation-renaturation chromatography and mobility-shift experiments. Two DNA-protein complexes were detected, which appeared to be sequence specific in competition experiments. Purification by hydroxyapatite, phosphocellulose, and reversed-phase high-pressure liquid chromatography separated two polypeptides with apparent molecular masses of 32 and 44 kD. Both proteins bound to conserved structures of the pea atp9 and the heterologous Oenothera berteriana atp1 promoters and to sequences just upstream. Possible functions of these proteins in mitochondrial promoter recognition are discussed.

Position-specific inhibition of yeast mitochondrial transcription by a poly(T) sequence

The 3' flanking nucleotide(s) of the octanucleotide promoter sequence regulates transcriptional efficiency of some mitochondrial genes in Saccharomyces cerevisiae. To understand this regulation the in vitro transcriptional activity of various synthetic mitochondrial promoters carrying different 3' flanking sequences was examined. The results presented here demonstrate that consecutive thymidine residues, but no other polynucleotides or secondary structure, in the promoter-proximal non-transcribed DNA strand inhibited mitochondrial transcription. The location and the number of T residues in the cluster as well as the concentration of UTP in the transcription reaction are the important factors determining this transcriptional inhibition. For example, a pair of thymidine nucleotides at positions +2 and +3 is sufficient for inactivation of mitochondrial transcription, whereas more than three consecutive thymidine nucleotides beyond these positions are required for inhibition of mitochondrial transcription. However, a cluster of six to 12 thymidine residues beyond position +11, a point where mtRNA polymerase has been shown to form a stable transcription complex, did not interfere with mitochondrial transcription. Interestingly, at low UTP concentration the mtRNA polymerase generates a large quantity of aborted initiation products on a template carrying promoter-proximal poly(T) sequence probably due to the inability of the polymerase to clear this promoter. On the other hand at high UTP concentration the same mtRNA polymerase on the same mitochondrial promoter produces a higher level of productive initiation complex. These observations suggest that the mechanism of poly(T) inhibition of mitochondrial transcription is a UTP-limited transcriptional attenuation at the promoter site, which might occur under specific physiological conditions (i.e. glucose repression-derepression, switching of aerobic-anaerobic conditions).

Identification of three regions essential for interaction between a sigma-like factor and core RNA polymerase

The cyclic interactions that occur between the subunits of the yeast mitochondrial RNA polymerase can serve as a simple model for the more complex enzymes in prokaryotes and the eukaryotic nucleus. We have used two-hybrid and fusion protein constructs to analyze the requirements for interaction between the single subunit core polymerase (Rpo41p), and the sigma-like promoter specificity factor (Mtf1p). We were unable to define any protein truncations that retained the ability to interact, indicating that multiple regions encompassing the entire length of the proteins are involved in interactions. We found that 9 of 15 nonfunctional (petite) point mutations in Mtf1p isolated in a plasmid shuffle strategy had lost the ability to interact. Some of the noninteracting mutations are temperature-sensitive petite (ts petite); this phenotype correlates with a precipitous drop in mitochondrial transcript abundance when cells are shifted to the nonpermissive temperature. One temperature-sensitive mutant demonstrated a striking pH dependence for core binding in vitro, consistent with the physical properties of the amino acid substitution. The noninteracting mutations fall into three widely spaced clusters of amino acids. Two of the clusters are in regions with amino acid sequence similarity to conserved regions 2 and 3 of sigma factors and related proteins; these regions have been implicated in core binding by both prokaryotic and eukaryotic sigma-like factors. By modeling the location of the mutations using the partial structure of Escherichia coli sigma70, we find that two of the clusters are potentially juxtaposed in the three-dimensional structure. Our results demonstrate that interactions between sigma-like specificity factors and core RNA polymerases require multiple regions from both components of the holoenzymes.

Cloning and characterization of a cDNA encoding a bacteriophage-type RNA polymerase from the higher plant Chenopodium album

We have cloned a full-length cDNA from the higher plant Chenopodium album coding for a single subunit bacteriophage-type RNA polymerase. The cDNA isolated from an actively growing cell suspension culture recognized a 3.8 kb transcript on Northern blots. The open reading frame comprises 987 amino acids with a predicted molecular mass of 112 kDa. A comparison of the protein sequence with those of the two known fungal mitochondrial RNA polymerases, from Saccharomyces cerevisiae and Neurospora crassa , reveals extensive homology between the three enzymes. with complete conservation of all catalytically essential amino acids. The putative mitochondrial RNA polymerase from C.album , as well as homologous sequences from rice and barley, which have been partially cloned, lack two catalytically non-essential regions of up to 176 amino acids near the C-terminus present in the two fungal mitochondrial RNA polymerases. The extreme N-terminus of the cloned C.album RNA polymerase displays features of a potential mitochondrial transit sequence. In phylogenetic trees constructed to compare the evolutionary relationships between the different single subunit RNA polymerases the C.album sequence forms a subgroup together with the S.cerevisiae and the N.crassa mitochondrial RNA polymerases, well separating from both bacteriophage enzymes and plasmid-encoded RNA polymerases found in mitochondria of many fungi and some higher plants.

Unusual usage of noncomplementary dinucleotide primers by the yeast mitochondrial RNA polymerase

The mitochondrial RNase P RNA gene in yeast Saccharomyces cerevisiae is transcribed from a variant mitochondrial promoter (SP). The sequence of this SP promoter [TATAAGAAG (+2)] differs from the conserved mitochondrial promoter sequence [TATAAGTAA (+2)] by-1T-->A and +2A-->G nucleotide substitutions. To determine the effect of these nucleotide alterations in mitochondrial promoter function, an in vitro transcription analysis was carried out. In the presence of high concentrations of rNTPs (i.e., 125 microM), transcription initiation on the wild-type or variant promoter occurred at the conventional 3' adenine nucleotide. However, at low rNTP concentrations (i.e., 5 microM) and in the presence of a complementary dinucleotide primer corresponding to positions -1 + 1, the mitochondrial RNA polymerase started transcription one nucleotide upstream of the conventional start site. Surprisingly, in the presence of some noncomplementary dinucleotides (i.e., GpA or CpA), which do not have perfect Watson-Crick base pairing with the initiator sequence, transcriptional initiation also occurred with the SP promoter but not with the conserved promoter sequence. This finding is the first example of utilization of noncomplementary dinucleotide primer by an RNA polymerase. Further analysis of mitochondrial promoter function by site-directed mutagenesis determined that the guanine nucleotide at position +2 is mainly responsible for this unusual function of the SP promoter.

Mitochondrial transcription initiation: promoter structures and RNA polymerases

A diversity of promoter structures. It is evident that tremendous diversity exists between the modes of mitochondrial transcription initiation in the different eukaryotic kingdoms, at least in terms of promoter structures. Within vertebrates, a single promoter for each strand exists, which may be unidirectional or bidirectional. In fungi and plants, multiple promoters are found, and in each case, both the extent and the primary sequences of promoters are distinct. Promoter multiplicity in fungi, plants and trypanosomes reflects the larger genome size and scattering of genes relative to animals. However, the dual roles of certain promoters in transcription and replication, at least in yeast, raises the interesting question of how the relative amounts of RNA versus DNA synthesis are regulated, possibly via cis-elements downstream from the promoters. Mitochondrial RNA polymerases. With respect to mitochondrial RNA polymerases, characterization of human, mouse, Xenopus and yeast enzymes suggests a marked degree of conservation in their behavior and protein composition. In general, these systems consist of a relatively non-selective core enzyme, which itself is unable to recognize promoters, and at least one dissociable specificity factor, which confers selectivity to the core subunit. In most of these systems, components of the RNA polymerase have been shown to induce a conformational change in their respective promoters and have also been assigned the role of a primase in the replication of mtDNA. While studies of the yeast RNA polymerase have suggested it has both eubacterial (mtTFB) and bacteriophage (RPO41) origins, it is not yet clear whether these characteristics will be conserved in the mitochondrial RNA polymerases of all eukaryotes. mtTFA-mtTFB; conserved but dissimilar functions. With respect to transcription factors, mtTFA has been found in both vertebrates and yeast, and may be a ubiquitous protein in mitochondria. However, the divergence in non-HMG portions of the proteins, combined with differences in promoter structure, has apparently relegated mtTFA to alternative, or at least non-identical, physiological roles in vertebrates and fungi. The relative ease with which mtTFA can be purified (Fisher et al. 1991) suggests that, where present, it should be facile to detect. mtTFB may represent a eubacterial sigma factor adapted for interaction with the mitochondrial RNA polymerase.(ABSTRACT TRUNCATED AT 400 WORDS)

Import of transcription factor MTF1 into the yeast mitochondria takes place through an unusual pathway

We report studies of the import into mitochondria of MTF1, a nucleus-encoded factor that markedly stimulates the specific transcription of mitochondrial DNA. Unlike most of the mitochondrial precursor proteins studied so far, import of MTF1 does not appear to require a receptor on the outer membrane, membrane potential across the inner membrane, or ATP hydrolysis. Its import is not affected by low temperature. It lacks a cleavable presequence but translocates across the inner membrane through its amino terminus; its sorting is independent of hsp60. Our results indicate an unusual and distinct import pathway for MTF1 into the yeast mitochondria.

A Saccharomyces cerevisiae mitochondrial transcription factor, sc-mtTFB, shares features with sigma factors but is functionally distinct

In Saccharomyces cerevisiae mitochondria, sc-mtTFB is a 341-amino-acid transcription factor required for initiation of transcription from mitochondrial DNA promoters. Specific transcription in vitro requires only sc-mtTFB and the bacteriophage-related core sc-mtRNA polymerase. Mutational analysis of sc-mtTFB has defined two regions of the protein that are important for normal function both in vivo and in vitro. These regions overlap portions of the protein that exhibit similarity to conserved region 2 of bacterial sigma factors. One mutation in this region of sc-mtTFB (tyrosine 108 to arginine [Y108R]) has a defective phenotype that matches that observed for mutations in the corresponding residue of Bacillus subtilis sigma A and sigma E proteins. However, mutations in the sigma 2.4-like region, including a 5-amino-acid deletion corresponding to crucial promoter-contacting amino acids of sigma factors, did not eliminate the ability of sc-mtTFB to initiate transcription specifically in vitro. This suggests a mechanism of promoter recognition for sc-mtRNA polymerase different from that used by bacterial RNA polymerases. Two mutations in a basic region of sc-mtTFB resulted in defective proteins that were virtually dependent on supercoiled DNA templates in vitro. These mutations may have disrupted a DNA-unwinding function of sc-mtTFB that is only manifested in vitro and is partially rescued by DNA supercoiling.

A persistent RNA-DNA hybrid is formed during transcription at a phylogenetically conserved mitochondrial DNA sequence

Critical features of the mitochondrial leading-strand DNA replication origin are conserved from Saccharomyces cerevisiae to humans. These include a promoter and a downstream GC-rich sequence block (CSBII) that encodes rGs within the primer RNA. During in vitro transcription at yeast mitochondrial replication origins, there is stable and persistent RNA-DNA hybrid formation that begins at the 5' end of the rG region. The short rG-dC sequence is the necessary and sufficient nucleic acid element for establishing stable hybrids, and the presence of rGs within the RNA strand of the RNA-DNA hybrid is required. The efficiency of hybrid formation depends on the length of RNA synthesized 5' to CSBII and the type of RNA polymerase employed. Once made, the RNA strand of an RNA-DNA hybrid can serve as an effective primer for mitochondrial DNA polymerase. These results reveal a new mechanism for persistent RNA-DNA hybrid formation and suggest a step in priming mitochondrial DNA replication that requires both mitochondrial RNA polymerase and an rG-dC sequence-specific event to form an extensive RNA-DNA hybrid.

Nucleo-mitochondrial interactions in mitochondrial gene expression

All proteins encoded by mitochondrial DNA (mtDNA) are dependent on proteins encoded by nuclear genes for their synthesis and function. Recent developments in the identification of these genes and the elucidation of the roles their products play at various stages of mitochondrial gene expression are covered in this review, which focuses mainly on work with the yeast Saccharomyces cerevisiae. The high degree of evolutionary conservation of many cellular processes between this yeast and higher eukaryotes, the ease with which mitochondrial biogenesis can be manipulated both genetically and physiologically, and the fact that it will be the first organism for which a complete genomic sequence will be available within the next 2 to 3 years makes it the organism of choice for drawing up an inventory of all nuclear genes involved in mitochondrial biogenesis and for the identification of their counterparts in other organisms.

In organello footprint analysis of human mitochondrial DNA: human mitochondrial transcription factor A interactions at the origin of replication

Using in organello footprint analysis, we demonstrate that within human placental mitochondria there is a high level of protein-DNA binding at regularly phased intervals throughout a 500-bp region encompassing the D-loop DNA origins and two promoter regions. Comparison with in vitro DNase I protection studies indicates that this protein-DNA interaction is due to non-sequence-specific binding by human mitochondrial transcription factor A (h-mtTFA). Since h-mtTFA can bend and wrap DNA, like its yeast counterpart ABF2, a primary function of h-mtTFA appears to be specific packaging of the mitochondrial DNA control region in vivo. Intervals of protein binding coincide with the spacing of the RNA start sites and prominent D-loop DNA 5' ends, suggesting a role for phased h-mtTFA binding in defining transcription and H-strand DNA replication origins. Significant protein-DNA interaction was also observed within the human homolog of conserved sequence block 1, both in organello and in vitro, using purified h-mtTFA.

In organello footprint analysis of human mitochondrial DNA: human mitochondrial transcription factor A interactions at the origin of replication

Using in organello footprint analysis, we demonstrate that within human placental mitochondria there is a high level of protein-DNA binding at regularly phased intervals throughout a 500-bp region encompassing the D-loop DNA origins and two promoter regions. Comparison with in vitro DNase I protection studies indicates that this protein-DNA interaction is due to non-sequence-specific binding by human mitochondrial transcription factor A (h-mtTFA). Since h-mtTFA can bend and wrap DNA, like its yeast counterpart ABF2, a primary function of h-mtTFA appears to be specific packaging of the mitochondrial DNA control region in vivo. Intervals of protein binding coincide with the spacing of the RNA start sites and prominent D-loop DNA 5' ends, suggesting a role for phased h-mtTFA binding in defining transcription and H-strand DNA replication origins. Significant protein-DNA interaction was also observed within the human homolog of conserved sequence block 1, both in organello and in vitro, using purified h-mtTFA.

ERV1 is involved in the cell-division cycle and the maintenance of mitochondrial genomes in Saccharomyces cerevisiae

In former studies it was found that the ERV1 gene is essential for cell viability and for the biogenesis of functional mitochondria. A temperature-sensitive nuclear mutant exhibits a severe reduction in all the mitochondrial transcripts. Elimination of the gene leads to growth arrest after a few cell divisions. The putative gene product bears the characteristics of a regulatory factor since it has low expression rate and a high content of charged amino acids. In this study it is further verified that the ERV1 gene alone is responsible for the observed cellular and mitochondrial defects. The 5' region of the gene is analysed by DNA deletions and complementation studies. Expression of the gene under the control of the GAL1-10 promoter in a disruption strain of ERV1 allows a more detailed specification ot its influence on mitochondrial and cellular functions. Immediate and complete loss of mitochondrial genomes is observed after the promoter has been shut off, whereas the yeast cells are still able to grow for a limited time under these conditions. Analysis of the cells by in-vivo DNA fluorescence demonstrates a specific arrest in the cell-division cycle as the terminal phenotype. To further characterize the temperature-sensitive allele of ERV1 the mutated gene has been isolated and sequenced. A single point mutation which leads to the exchange of a single amino acid is found in the reading frame.

A new nuclear suppressor system for a mitochondrial RNA polymerase mutant identifies an unusual zinc-finger protein and a polyglutamine domain protein in Saccharomyces cerevisiae

A yeast strain with a point mutation in the nuclear gene for the core subunit of mitochondrial RNA polymerase was used to isolate new extragenic suppressors. Spontaneously occurring phenotypical revertants were analysed by crosses with the wild-type and tetrad dissection. One of the new nuclear suppressor mutants was characterized by temperature-sensitive growth on non-fermentable carbon sources. This mutant was transformed with a genomic yeast library. Two independent types of DNA clones were isolated which both complemented the temperature-sensitive defect. Subcloning and DNA sequencing identified two novel yeast genes which code for proteins with the characteristic features of transcription factors. Both factors exhibit highly structured protein domains consisting of runs and clusters of asparagine and glutamine residues. One of the proteins contains in addition zinc-finger domains of the C2H2-type. Therefore the genes are proposed to be named AZF1 (asparagine-rich zinc-finger protein) and PGD1 (polyglutamine domain protein). Gene disruption of both reading frames has no detectable influence on the vegetative growth on complete glucose or glycerol media, indicating that the genes may act as high copy number suppressors of the mutant defect. Additional transformation experiments showed that AZF1 is also an efficient suppressor for the original defect in the core subunit of mitochondrial RNA polymerase.

MTF1, encoding the yeast mitochondrial RNA polymerase specificity factor, is located on chromosome XIII

MTF1 is a nuclear gene that encodes the promoter recognition factor of the yeast mitochondrial RNA polymerase. The MTF1 gene was physically mapped to chromosome XIII. Genetic mapping data indicate that the gene is closely linked to RNA1.