Regulation and function of the mitochondrial genome.

Molecular changes in human mitochondrial DNA play a significant role in causing certain human diseases. Mitochondrial DNA mutations range from single base pair changes in the 16.5 kilobase pair genome up to large deletions and rearrangements. This report summarizes the current overall understanding of the mode and mechanism of mitochondrial DNA replication and transcription, and how this relates to mitochondrial gene expression, which is essential for cellular energy production and organelle biogenesis. Special attention is given to recent findings that bear on early steps in the process of transcription and, in turn, the consequences for initiating DNA replication.

Subtle determinants of the nucleocytoplasmic partitioning of in vivo-transcribed RNase MRP RNA in Xenopus laevis oocytes.

RNase MRP is a ribonucleoprotein originally identified on the basis of its ability to cleave RNA endonucleolytically from origins of mitochondrial DNA replication, rendering it a likely candidate for a role in priming leading-strand synthesis of mtDNA. In addition, a nuclear role for RNase MRP has been identified in yeast (Saccharomyces cerevisiae) ribosomal RNA processing. Consistent with a duality of function, RNase MRP has been localized to both mitochondria and nucleoli by in situ techniques. The RNA component of this ribonucleoprotein has been characterized from several different species. We previously cloned the gene for Xenopus laevis MRP RNA and showed that RNase MRP RNA is differentially expressed during amphibian development; in addition, the microinjected X. laevis RNase MRP RNA gene is correctly and efficiently transcribed in vivo. This article presents an analysis of the intracellular movement of in vivo-transcribed RNase MRP RNA in microinjected mature X. laevis oocytes. Although X. laevis MRP RNA is assembled into a ribonucleoprotein form and transported in an expected manner, human and mouse MRP RNAs exhibit markedly different transport patterns even though they are highly conserved in primary sequence. Furthermore, the only currently assigned protein (Th autoantigen) binding site in MRP RNA can be deleted without loss of nuclear export capacity. These results indicate that subtle determinants must exist for nucleocytoplasmic partitioning of this RNP and that the conserved Th autoantigen binding region appears unnecessary for the transit of in vivo-transcribed MRP RNA to the cytoplasm of mature X. laevis oocytes.

Distribution of RNase MRP RNA during Xenopus laevis oogenesis.

RNase MRP is a ribonucleoprotein endoribonuclease found predominantly in nucleoli, but which has been associated with mitochondria and mitochondrial RNA processing. In order to analyze the intracellular localization of specific RNA components of ribonucleoproteins of this type, a whole-mount method for in situ hybridization in Xenopus laevis oocytes was employed. Results with specific probes (for both mitochondrial and nonmitochondrial RNAs) indicate that this procedure is generally effective for the detection of a variety of nucleic acids that reside in different cellular compartments. Probes used to detect the endogenous RNA component of RNase MRP (MRP RNA) during X. laevis oogenesis revealed a continuous nuclear signal as well as a possible dual localization of MRP RNA in nucleoli and mitochondria at developmental stages temporally consistent with both ribosomal and mitochondrial biogenesis. Genomic DNA encoding MRP RNA was injected into the nuclei of stage VI oocytes and correctly transcribed. The in vivo-transcribed RNA was properly assembled with at least some of its cognate proteins as demonstrated by immunoprecipitation with specific autoantiserum. In addition, detectable levels of the RNA were exported to the cytoplasm. This whole-mount procedure has permitted us to identify MRP RNA in situ at different developmental time points as well as during transcription of the injected gene, and suggests differential localization of MRP RNA during oogenesis consistent with its proposed function in both mitochondria and nucleoli.

Distribution of exchanges upon homologous recombination of exogenous DNA in Xenopus laevis oocytes.

Homologous recombination between DNA molecules injected into Xenopus oocyte nuclei was investigated by examining the recovery of information from differentially marked parental sequences. The injected recombination substrate was a linear DNA with terminal direct repeats of 1246 bp; one repeat differed from the other by eight single base-pair substitutions, distributed throughout the region of homology, each of which created or destroyed a restriction enzyme site. Recombination products were recovered and analyzed for their content of the diagnostic sites, either directly by Southern blot-hybridization or after cloning in bacteria. The majority (76%) of the cloned products appeared to be the result of simple exchanges-i.e., there was one sharp transition from sequences derived from one parent to sequences derived from the other. These simple exchanges were concentrated near the ends of the homologous interval and, thus, near the sites of the original molecular ends. Placing marked sites on only one side of the homologous overlap showed that marker recovery was governed largely by the positions of the molecular ends and not by the markers themselves. When a terminal nonhomology was present at one end of the substrate, the yield of recombinants was sharply decreased, but the pattern of exchanges was not affected, suggesting that products from end-blocked substrates arise by the same recombination pathway. Because of considerable evidence supporting a nonconservative, resection-annealing mechanism for recombination in oocytes, we interpret the distribution of exchanges as resulting from long-patch repair of extensive heteroduplex intermediates.

Repair of heteroduplex DNA in Xenopus laevis oocytes.

We have hypothesized that the inheritance of heteroallelic markers during recombination of homologous DNAs in Xenopus oocytes is determined by resolution of a heteroduplex intermediate containing multiple single-base mismatches. To test this idea, we prepared synthetic heteroduplexes carrying 8 separate mispairs in vitro and injected them into oocyte nuclei. DNA was recovered and analyzed directly, by Southern blot-hybridization, and indirectly, by cloning individual repair products in bacteria. Mismatch correction was quite efficient in the oocytes; markers on the same strand were commonly co-corrected, indicating a long-patch mechanism; and the distribution of markers was very similar to that obtained by recombination. This supports our interpretation of the recombination outcome in terms of a resection-annealing mechanism. The injected heteroduplexes carried strand breaks (nicks) as a result of their method of preparation. We tested the idea that mismatch correction might be nick-directed by ligating the strands of the heteroduplex substrate to form covalently closed circles. Repair in oocytes was still efficient, and long patches predominated; but the pattern of recovered markers was quite different than with the nicked substrate. This suggests that nicks, when present, do indeed direct repair, but that, in their absence, recognition of specific mismatches governs repair of the ligated heteroduplexes.

Effect of terminal nonhomologies on homologous recombination in Xenopus laevis oocytes.

Homologous recombination of linear DNA molecules in Xenopus laevis oocytes is very efficient. The predictions of molecular models for this recombination process were tested with substrates with terminal nonhomologies (nonhomologous sequences). It was found that nonhomologies on one or both ends of an otherwise efficient substrate substantially reduced the yield of recombination products. In the case of a single nonhomology, inhibition was observed for all lengths of nonhomology, from 60 to 1,690 bp, being most dramatic for the longer blocks. Examination of time courses of recombination showed that the blocks were largely kinetic; that is, substrates with short nonhomologies eventually yielded substantial levels of completed products. Intermediates that accumulated after the injection of end-blocked substrates were characterized by two-dimensional gel electrophoresis and hybridization with strand-specific oligonucleotide probes. These blocked intermediates were shown to have base-paired junctions, but resolution was prevented by the failure to remove the 3'-ending strand of the original nonhomology. Continuing exonuclease action created a single-strand gap adjacent to the position of the persistent nonhomology. In contrast, the strand that included the unblocked side of the junction could be sealed. These results are consistent with a nonconservative, resection-annealing mechanism of homologous recombination in the oocytes and suggest the absence of any activity that can efficiently remove 3' tails.

Characterization of a Xenopus laevis ribonucleoprotein endoribonuclease. Isolation of the RNA component and its expression during development.

In order to facilitate studies of the assembly and transport of the site-specific RNase mitochondrial RNA processing (MRP) ribonucleoprotein, we have characterized it from Xenopus laevis cells. X. laevis RNase MRP displayed a similar spectrum of cleavage activity to that produced by previously isolated mammalian nuclear enzymes. A 277-nucleotide RNA component of the ribonucleoprotein was identified; the gene for the RNA was isolated, sequenced, and found to be 66 and 63% similar to mouse and human RNase MRP RNAs, respectively. Despite the evolutionary distance from its mammalian counterparts, X. laevis RNase MRP RNA contains five regions of homology to the mammalian RNase MRP RNA. Four of these regions correspond to those previously identified as conserved between RNase MRP and RNase P RNAs; the fifth encompasses nucleotides recently discovered to be sufficient for autoantigen binding. The expression and assembly of Xenopus RNase MRP RNA were examined in frog oocytes and developing embryos. RNase MRP RNA was expressed throughout oogenesis; it started to accumulate at stage I and reached a maximum in stage IV. During embryogenesis RNase MRP RNA expression began to elevate at approximately stage 22 and continued to rise through the swimming tadpole stage. When injected into the nucleus of mature oocytes, the X. laevis RNase MRP RNA gene was expressed accurately, and transcripts were packaged into immunoprecipitable particles.

Test of the double-strand-break repair model of recombination in Xenopus laevis oocytes.

A direct test was made of predictions of the double-strand-break repair (DSBR) model of recombination in Xenopus laevis oocytes. The DNA substrate injected into oocytes had two directly repeated copies of a 1.25-kb sequence and was cleaved within one of them. Different products were expected to result from concerted, conservative events, as predicted by the DSBR model, and from nonconservative events. Only very low levels of recombination products, both conservative and nonconservative, were observed. When individual, apparent DSBR products were cloned and characterized, it emerged that the majority of them had arisen by nonconservative recombination through short, terminal homologies and not from the gene conversion events predicted for DSBR. Two cloned products among 44 tested corresponded to the predications of the DSBR model, but these could also have been generated by other processes. The most efficient recombination events in oocytes are nonconservative and are based on long, terminal homologous overlaps; when these are not available, short, imperfect overlaps support a lower level of nonconservative recombination; genuine, conservative DSBR events occur rarely, if at all.