The primase domain of PfPrex is a proteolytically matured, essential enzyme of the apicoplast

The apicoplast of Plasmodium is an essential organelle with its own circular genome that must be faithfully replicated and segregated to its progeny during parasite sporogony and schizogony. DNA replication proteins are not encoded by its genome. Instead, the replication machinery must be imported from nuclear-encoded genes. A likely apicoplast DNA replication factor, PfPrex, bears a bipartite leader sequence for apicoplast trafficking and contains several DNA replication-related enzymatic domains. Here we analyze the domain structure of PfPrex and examine its trafficking and maturation within the parasite. A minimal primase domain of PfPrex is shown to contain functional zinc-binding and TOPRIM-fold domains, which in a recombinant form are sufficient to produce RNA primers from a single-stranded DNA template. PfPrex is shown to be extensively proteolytically matured within the parasite, which effectively separates its functional domains. Gene targeting attempts to knockout the Plasmodium yoelii ortholog of Prex were unsuccessful, indicating the apparent essentiality of this protein to the parasite. Finally, overexpression in Plasmodium falciparum of PfPrex's trafficking and primase sequences yielded specific and dynamic localization to foci within the apicoplast. Taken together, these observations strongly suggest an essential role of PfPrex primase in the production of RNA primers for lagging strand DNA synthesis of the apicoplast genome.     

Gene organization of the mitochondrial DNA of yeasts: Kluyveromyces lactis and Saccharomycopsis lipolytica

Summary Restriction fragment maps have been constructed for the mitochondrial DNA from two petitenegative yeasts, Kluyveromyces lactis and Saccharomycopsis lipolytica (Candida lipolytica). On these circular genomes, we localized the sequences homologous to the S. cerevisiae mtDNA fragments carrying known genes. The arrangement of genes for ATPase subunit proteins, ribosomal RNA and 4S RNA shows a common feature with respect to S. cerevisiae mitochondrial genome.Abbreviations bp base pairs - mtDNA mitochondrial DNA - tRNA transfer RNA - rRNA ribosomal RNA     

Mitochondrial Encephalomyopathies: Defects of Nuclear DNA

The term "mitochondrial diseases" encompasses a heterogeneous group of disorders in which a primary mitochondrial dysfunction is suspected or proven by morphologic, genetic, or biochemical criteria. Clinically, these progressive disorders usually affect muscle, either alone (mitochondrial myopathies) or in combination with other systems, most often brain (encephalomyopathies). Mitochondria are unique among intracellular organelles in that mitochondrial proteins are encoded by two genomes, nuclear DNA (nDNA) and mitochondrial DNA (mtDNA). The vast majority of mitochondrial proteins are encoded by the nuclear genome, whereas mtDNA (a circular, double stranded 16.5 kb molecule) encodes only 13 polypeptides, all of them subunits of respiratory chain complexes. In addition to structural genes, mtDNA also codes for 22 transfer RNAs and two ribosomal RNAs. Our understanding of mitochondrial diseases has grown at an impressive rate in the past few years, and most of the progress has been in the area of mtDNA genetics, where several mtDNA mutations have been associated with specific diseases (reviewed in this issue by Zeviani et al.). In comparison, our understanding of mitochondrial disorders due to nDNA lesions has lagged behind and, to date, molecular defects of nuclear genes have been documented in only a few patients. We will review which alterations in the nuclear genome can cause mitochondrial disorders and which criteria are useful in identifying such mutations. While several examples will be provided, this is not intended as a complete review of the subject.     

Reaching for the ring: the study of mitochondrial genome structure

The linear molecules that comprise most of the mitochondrial DNA (mtDNA) isolated from most organisms result from the artifactual degradation of circular genomes that exist within mitochondria. This view has been adopted by most investigators and is based on DNA fragment mapping data as well as analogy to the genomesized circular mtDNA molecules obtained in high yield from animals. The alternative view that linear molecules actually represent the major form of DNA within mitochondria is supported by two observations: (1) over a 1000-fold range of genome size among fungi and plants we find the same size distribution of linear mtDNA molecules, and (2) linear mtDNA molecules much larger than genome size can be found for some fungi and plants. The circles that represent only a small fraction of the mtDNA obtained from most eukaryotes could be optional sequence forms unimportant for mitochondrial function; they may also participate in mtDNA replication. The circles might result from incidental recombination events between directly repeated sequences within or between tandemly arrayed genome units on linear mtDNA molecules.     

Depletion of the other genome-mitochondrial DNA depletion syndromes in humans

We present the current knowledge on the genetic and phenotypic aspects of mitochondrial DNA depletion syndromes. The human mitochondrial DNA encodes 13 of the 82 structural proteins of the mitochondrial electron transport chain. The replication and maintenance of the mtDNA require a large number of nuclear encoded enzymes and balanced nucleotide pools. Mitochondrial nucleotide synthesis is of major importance because of the constant need for nucleotides for mtDNA maintenance even in quiescent cells. As de novo enzymes are not present in the mitochondria, synthesis is accomplished via the salvage pathway. Defective mtDNA synthesis and maintenance manifest by multiple deletions or by depletion of the mitochondrial genome. Patients with multiple deletions typically present with progressive external ophthalmoplegia, ptosis and, exercise intolerance after the first decade of life. mtDNA depletion is usually an infantile disease characterized by severe muscle weakness, hepatic failure, or renal tubulopathy with fatal outcome. Linkage analysis in families with multiple mtDNA deletions reveal mutations in proteins that participate in mtDNA replication, the mitochondrial DNA polymerase gene, and the Twinkle gene, a putative mitochondrial helicase and in factors which play a role in mitochondrial nucleotide metabolism, the adenine nucleotide translocator, and the thymidine phosphorylase gene. We have recently identified mutations in an additional two essential proteins in the nucleotide salvage pathway, the mitochondrial deoxyribonucleoside kinases. The phenotype was distinctive for each gene, with hepatic failure and encephalopathy associated with mutations in the deoxyguanosine kinase gene and isolated devastating myopathy as the sole manifestation of thymidine kinase 2 deficiency. The tissue selectivity of these disorders and especially the exclusive muscle involvement in thymidine kinase 2 mutations is puzzling. The normal sequence of the remaining mtDNA copies in spite of a serious mitochondrial nucleotide imbalance is also unexpected. We propose several tissue-specific protective mechanisms and a time window, likely encompassing fetal life and even early infancy, during which nuclear nucleotide synthesis provides mitochondrial needs in all organs. We also speculate on future genes to be discovered in other phenotypes of mtDNA depletion.     

Autonomously replicating sequences in young and senescent mitochondrial DNA from Podospora anserina

Summary Senescence in the filamentous fungus Podospora anserina is characterized by the accumulation of multimeric circular mitochondrial DNA molecules, known as senDNAs. These tandemly repeated DNA sequences, which originate from broadly dispersed regions of the young mitochondrial genome, behave as independently replicating molecules. In this study, the yeast transformation system was used to assay senDNAs and their young mtDNA counterparts for the presence of autonomously replicating sequences. P. anserina mtDNA fragments were cloned into the yeast vector YIp5 and the hybrid YPM plasmids were used to transform yeast. All of the senDNAs and their homologous young mtDNAs promoted high frequency transformation and extrachromosomal maintenance of YPM plasmids. The putative origin of replication for the P. anserina mitochondrial genome was also cloned into YIp5 and shown to confer autonomously replicating properties.     

Role of the mitochondrial DNA replication machinery in mitochondrial DNA mutagenesis,aging and age-related diseases

As regulators of bioenergetics in the cell and the primary source of endogenous reactive oxygen species (ROS), dysfunctional mitochondria have been implicated for decades in the process of aging and age-related diseases. Mitochondrial DNA (mtDNA) is replicated and repaired by nuclear-encoded mtDNA polymerase γ (Pol γ) and several other associated proteins, which compose the mtDNA replication machinery. Here, we review evidence that errors caused by this replication machinery and failure to repair these mtDNA errors results in mtDNA mutations. Clonal expansion of mtDNA mutations results in mitochondrial dysfunction, such as decreased electron transport chain (ETC) enzyme activity and impaired cellular respiration. We address the literature that mitochondrial dysfunction, in conjunction with altered mitochondrial dynamics, is a major driving force behind aging and age-related diseases. Additionally, interventions to improve mitochondrial function and attenuate the symptoms of aging are examined.