David A. Clayton

A Generalization of the Transmission/Disequilibrium Test for Uncertain-Haplotype Transmission

A new transmission/disequilibrium-test statistic is proposed for situations in which transmission is uncertain. Such situations arise when transmission of a multilocus marker haplotype is considered, since haplotype phase is often unknown in a substantial number of instances. Even for single-locus markers, transmission is uncertain if one or both parents are missing. In both these situations, uncertainty may be reduced by the typing of further siblings, whose disease status may be unaffected or unknown. The proposed test is a score test based on a partial score function that omits the terms most influenced by hidden population stratification.

Dilated cardiomyopathy and atrioventricular conduction blocks induced by heart-specific inactivation of mitochondrial DNA gene expression

Mutations of mitochondrial DNA (mtDNA) cause several well-recognized human genetic syndromes with deficient oxidative phosphorylation and may also have a role in ageing and acquired diseases of old age. We report here that hallmarks of mtDNA mutation disorders can be reproduced in the mouse using a conditional mutation strategy to manipulate the expression of the gene encoding mitochondrial transcription factor A (Tfam, previously named mtTFA), which regulates transcription and replication of mtDNA (Refs 6,7). Using a loxP-flanked Tfam allele (TfamloxP; ref. 8) in combination with a cre-recombinase transgene under control of the muscle creatinine kinase promoter9,10, we have disrupted Tfam in heart and muscle. Mutant animals develop a mosaic cardiac-specific progressive respiratory chain deficiency, dilated cardiomyopathy, atrioventricular heart conduction blocks and die at 2-4 weeks of age. This animal model reproduces biochemical, morphological and physiological features of the dilated cardiomyopathy of Kearns-Sayre syndrome. Furthermore, our findings provide genetic evidence that the respiratory chain is critical for normal heart function.

Yeast mitochondrial RNA polymerase is homologous to those encoded by bacteriophages T3 and T7

Analysis of the nucleotide sequence of the genetic locus for yeast mitochondrial RNA polymerase (RPO41) reveals a continuous open reading frame with the coding potential for a polypeptide of 1351 amino acids, a size consistent with the electrophoretic mobility of this enzymatic activity. The transcription product from this gene spans the singular reading frame. In vivo transcript abundance reflects codon usage and growth under stringent conditions for mitochondrial biogenesis and function results in a several fold higher level of gene expression than growth under glucose repression. A comparison of the yeast mitochondrial RNA polymerase amino acid sequence to those of E. coli RNA polymerase subunits failed to demonstrate any regions of homology. Interestingly, the mitochondrial enzyme is highly homologous to the DNA-directed RNA polymerases of bacteriophages T3 and T7, especially in regions most highly conserved between the T3 and T7 enzymes themselves.

Purification and characterization of human mitochondrial transcription factor 1.

We purified to near homogeneity a transcription factor from human KB cell mitochondria. This factor, designated mitochondrial transcription factor 1 (mtTF1), is required for the in vitro recognition of both major promoters of human mitochondrial DNA by the homologous mitochondrial RNA polymerase. Furthermore, it has been shown to bind upstream regulatory elements of the two major promoters. After separation from RNA polymerase by phosphocellulose chromatography, mtTF1 was chromatographed on a MonoQ anion-exchange fast-performance liquid chromatography column. Analysis of mtTF1-containing fractions by sodium dodecyl sulfate-polyacrylamide gel electrophoresis revealed a single major polypeptide with an Mr of approximately 25,000. Centrifugation in analytical glycerol gradients indicated a sedimentation coefficient of approximately 2.5 S, consistent with a monomeric 25-kilodalton protein. Finally, when the 25-kilodalton polypeptide was excised from a stained sodium dodecyl sulfate-polyacrylamide gel and allowed to renature, it regained DNA-binding and transcriptional stimulatory activities at both promoters. Although mtTF1 is the only mitochondrial DNA-binding transcription factor to be purified and characterized, its properties, such as a high affinity for random DNA and a weak specificity for one of its target sequences, may typify this class of regulatory proteins.

Transcription and Replication of Animal Mitochondrial DNAs

The development of in vitro transcription and replication systems has allowed the identification of promoter sequences and origins of replication for several animal mtDNAs. As a consequence, the necessary reagents and basic information are available to permit the characterization of transacting factors that are required for transcription and replication. All of the animal trans-acting species purified at this time are known or reasoned to be nuclear gene products. There is now the opportunity to learn how these nuclear genes are regulated and the mechanisms that are utilized for the import of their products into the organelle. With regard to import, the human transcription factor mtTF1 appears to have an amino-terminal sequence characteristic of other imported mitochondrial proteins (Parisi and Clayton, 1991). An interesting issue is the degree to which fundamental features of mtDNA replication and transcription are conserved between species. With regard to animal mtDNAs, there is very little in the way of conservation of DNA sequence at the promoters and origins of replication. The exceptions to this are the presence of a characteristic stem-loop L-strand origin of replication sequence in vertebrates [except for chicken mtDNA (Desjardins and Morais, 1990)] and the general presence of CSBs II and III (and to a lesser extent CSB I) in most higher animal mtDNAs. Because mtDNA promoters are not highly conserved, it is perhaps not surprising that general cross-species transcription does not occur, except for very limited examples of closely related species and sequences (Chang et al., 1985b). Using crude mtRNA polymerase holoenzyme preparations, there is no specific transcriptional initiation when proteins from human mitochondria are used with mouse mtDNA promoter templates, and vice versa. However, in contrast to this overall observation, purified fractions of human or mouse mtTF1 can be exchanged and shown to function across species boundaries (Fisher et al., 1989). The ability of mitochondrial mtTF1-type proteins to operate across even greater evolutionary distances was suggested by the ability of human and yeast proteins to recognize some mitochondrial promoter sequences in common (Fisher et al., 1992). More recent studies suggest that human mtTF1 can substitute for its yeast homolog in vivo, and thereby perform at least the most critical functions required to maintain yeast mtDNA in the cell (M.A. Parisi, B. Xu, and D.A. Clayton, submitted for publication). The other sites of conserved macromolecular interactions are related to the two origins of DNA replication.(ABSTRACT TRUNCATED AT 400 WORDS)

Mouse L cell mitochondrial DNA molecules are selected randomly for replication throughout the cell cycle

The number of mitochondrial DNA molecules in a cell population doubles at the same rate as the cell generation time. This could occur by a random selection of molecules for replication or by a process that ensures the replication of each individual molecule in the cell. We have investigated the rate at which mouse L cell mitochondrial DNA molecules labeled with 3H-thymidine during one round of replication are reselected for a second round of replication. Mouse L cells were labeled with 3H-thymidine for 2 hr, chased for various periods of time and then labeled with 5-bromodeoxyuridine for 4 hr immediately before mitochondrial DNA isolation. A constant fraction of 3H-thymidine-labeled mitochondrial DNA incorporated 5-bromodeoxyuridine after chase intervals ranging from 1.5-22 hr. This result demonstrates that mitochondrial DNA molecules replicated in a short time interval are randomly selected for later rounds of replication, and that replication of mitochondrial DNA continues throughout the cell cycle in mouse L cells.

Promoter selection in human mitochondria involves binding of a transcription factor to orientation-independent upstream regulatory elements

Selective transcription of human mitochondrial DNA requires a transcription factor (mtTF) in addition to an essentially nonselective RNA polymerase. Partially purified mtTF is able to sequester promoter-containing DNA in preinitiation complexes in the absence of mitochondrial RNA polymerase, suggesting a DNA-binding mechanism for factor activity. Functional domains, required for positive transcriptional regulation by mtTF, are identified within both major promoters of human mtDNA through transcription of mutant promoter templates in a reconstituted in vitro system. These domains are essentially coextensive with DNA sequences protected from nuclease digestion by mtTF-binding. Comparison of the sequences of the two mtTF-responsive elements reveals significant homology only when one sequence is inverted; the binding sites are in opposite orientations with respect to the predominant direction of transcription. Thus mtTF may function bidirectionally, requiring additional protein-DNA interactions to dictate transcriptional polarity. The mtTF-responsive elements are arrayed as direct repeats, separated by approximately 80 bp within the displacement-loop region of human mitochondrial DNA; this arrangement may reflect duplication of an ancestral bidirectional promoter, giving rise to separate, unidirectional promoters for each strand.

A human mitochondrial transcriptional activator can functionally replace a yeast mitochondrial HMG-box protein both in vivo and in vitro.

Human mitochondrial transcription factor A is a 25-kDa protein that binds immediately upstream of the two major mitochondrial promoters, thereby leading to correct and efficient initiation of transcription. Although the nature of yeast mitochondrial promoters is significantly different from that of human promoters, a potential functional homolog of the human transcriptional activator protein has been previously identified in yeast mitochondria. The importance of the yeast protein in yeast mitochondrial DNA function has been shown by inactivation of its nuclear gene (ABF2) in Saccharomyces cerevisiae cells resulting in loss of mitochondrial DNA. We report here that the nuclear gene for human mitochondrial transcription factor A can be stably expressed in yeast cells devoid of the yeast homolog protein. The human protein is imported efficiently into yeast mitochondria, is processed correctly, and rescues the loss-of-mitochondrial DNA phenotype in a yeast abf2 strain, thus functionally substituting for the yeast protein. Both human and yeast proteins affect yeast mitochondrial transcription initiation in vitro, suggesting that the two proteins may have a common role in this fundamental process.

Nuclear gadgets in mitochondrial DNA replication and transcription

In mammalian mitochondrial DNA, activation of the light-strand promoter mediates both priming of leading-strand replication and initiation of light-strand transcription. Accurate and efficient transcription requires at least two proteins: mitochondrial RNA polymerase and a separable transcription factor that can function across species boundaries. Subsequently, primer RNAs are cleaved by a site-specific ribonucleoprotein endoribonuclease that recognizes short, highly conserved sequence elements in the RNA substrate.

In vitro replication of human mitochondrial DNA: Accurate initiation at the origin of light-strand synthesis

Synthesis of human light-strand mitochondrial DNA was accomplished in vitro using DNA primase, DNA polymerase, and other accessory proteins isolated from human mitochondria. Replication begins with the synthesis of primer RNA on a T-rich sequence in the origin stem-loop structure of the template DNA and absolutely requires ATP. A transition from RNA synthesis to DNA synthesis occurs near the base of the stem-loop structure and a potential recognition site for signaling that transition has been identified. The start sites of the in vitro products were mapped at the nucleotide level and were found to be in excellent agreement with those of in vivo nascent light-strand DNA. Isolated human mitochondrial enzymes recognize and utilize the bovine, but not the mouse, origin of light-strand replication.