Purification and properties of a single strand-specific endonuclease from mouse cell mitochondria

EXOG, a novel paralog of Endonuclease G in higher eukaryotes

Evolutionary conserved mitochondrial nucleases are involved in programmed cell death and normal cell proliferation in lower and higher eukaryotes. The endo/exonuclease Nuc1p, also termed ‘yeast Endonuclease G (EndoG)’, is a member of this class of enzymes that differs from mammalian homologs by the presence of a 5′–3′ exonuclease activity in addition to its broad spectrum endonuclease activity. However, this exonuclease activity is thought to be essential for a function of the yeast enzyme in DNA recombination and repair. Here we show that higher eukaryotes in addition to EndoG contain its paralog ‘EXOG’, a novel EndoG-like mitochondrial endo/exonuclease. We find that during metazoan evolution duplication of an ancestral nuclease gene obviously generated the paralogous EndoG- and EXOG-protein subfamilies in higher eukaryotes, thereby maintaining the full endo/exonuclease activity found in mitochondria of lower eukaryotes. We demonstrate that human EXOG is a dimeric mitochondrial enzyme that displays 5′–3′ exonuclease activity and further differs from EndoG in substrate specificity. We hypothesize that in higher eukaryotes the complementary enzymatic activities of EndoG and EXOG probably together account for both, the lethal and vital functions of conserved mitochondrial endo/exonucleases.

The DNA double-stranded break repair protein endo-exonuclease as a therapeutic target for cancer

DNA repair mechanisms are crucial for the maintenance of genomic stability and are emerging as potential therapeutic targets for cancer. In this study, we report that the endo-exonuclease, a protein involved in the recombination repair process of the DNA double-stranded break pathway, is overexpressed in a variety of cancer cells and could represent an effective target for developing anticancer drugs. We identify a dicationic diarylfuran, pentamidine, which has been used clinically to treat opportunistic infections and is an inhibitor of the endo-exonuclease as determined by enzyme kinetic assay. In clonogenic and 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide assays as well as in the in vivo Lewis lung carcinoma mouse tumor model, pentamidine is shown to possess the ability to selectively kill cancer cells. The LD50 of pentamidine on cancer cells maintained in vitro is correlated with the endo-exonuclease enzyme activity. Tumor cell that has been treated with pentamidine is reduced in the endo-exonuclease as compared with the untreated control. Furthermore, pentamidine synergistically potentiates the cytotoxic effect of DNA strand break and cross-link-inducing agents such as mitomycin C, etoposide, and cisplatin. In addition, we used the small interfering RNA for the mouse homologue of the endo-exonuclease to down-regulate the level of endo-exonuclease in the mouse myeloma cell line B16F10. Down-regulation of the endo-exonuclease sensitizes the cell to 5-fluorouracil. These studies suggested the endo-exonuclease enzyme as a novel potential therapeutic target for cancer.

Single-strand-specific nucleases

Single-strand-specific nucleases are multifunctional enzymes and widespread in distribution. Their ability to act selectively on single-stranded nucleic acids and single-stranded regions in double-stranded nucleic acids has led to their extensive application as probes for the structural determination of nucleic acids. Intracellularly, they have been implicated in recombination, repair and replication, whereas extracellular enzymes have a role in nutrition. Although more than 30 single-strand-specific nucleases from various sources have been isolated till now, only a few enzymes (S1 nuclease from Aspergillus oryzae, P1 nuclease from Penicillium citrinum and nucleases from Alteromonas espejiana, Neurospora crassa, Ustilago maydis and mung bean) have been characterized to a significant extent. Recently, some of these enzymes have been cloned, their crystal structures solved and their interactions with different substrates have been established. The detection, purification, characteristics, structure-function correlations, biological role and applications of single-strand-specific nucleases are reviewed.

hMYH cell cycle-dependent expression, subcellular localization and association with replication foci: evidence suggesting replication-coupled repair of adenine:8-oxoguanine mispairs

The human MutY homolog, hMYH, is an adenine-specific DNA glycosylase that removes adenines or 2-hydroxyadenines mispaired with guanines or 8-oxoguanines. In order to prevent mutations, this activity must be directed to the newly synthesized strand and not the template strand during DNA synthesis. The subcellular localization and expression of hMYH has been studied in serum-stimulated, proliferating MRC5 cells. Using specific antibodies, we demonstrate that endogenous hMYH protein localized both to nuclei and mitochondria. hMYH in the nuclei is distinctly distributed and co-localized with BrdU at replication foci and with proliferating cell nuclear antigen (PCNA). The levels of hMYH in the nucleus increased 3- to 4-fold during progression of the cell cycle and reached maximum levels in S phase compared to early G(1). Similar results were obtained for PCNA, while there were no notable changes in expression of 8-oxoguanine glycosylase or the human MutT homolog, MTH1, throughout the cell cycle. The cell cycle-dependent expression and localization of hMYH at sites of DNA replication suggest a role for this glycosylase in immediate post-replication DNA base excision repair.

Extracellular nuclease from Rhizopus stolonifer: purification and characteristics of - single strand preferential - deoxyribonuclease activity

An extracellular nuclease from Rhizopus stolonifer (designated as nuclease Rsn) was purified to homogeneity by chromatography on DEAE-cellulose followed by Blue Sepharose. The M(r) of the purified enzyme determined by native PAGE was 67¿ omitted¿000 and it is a tetramer and each protomer consists of two unidentical subunits of M(r) 21¿ omitted¿000 and 13¿ omitted¿000. It is an acidic protein with a pI of 4.2 and is not a glycoprotein. The purified enzyme showed an obligate requirement of divalent cations like Mg(2+), Mn(2+) and Co(2+) for its activity but is not a metalloprotein. The optimum pH of the enzyme was 7.0 and was not influenced by the type of metal ion used. Although, the optimum temperature of the enzyme for single stranded (ss) DNA hydrolysis in presence of all three metal ions and for double stranded (ds) DNA hydrolysis in presence of Mg(2+) was 40 degrees C, it showed higher optimum temperature (45 degrees C) for dsDNA hydrolysis in presence of Mn(2+) and Co(2+). Nuclease Rsn was inhibited by divalent cations like Zn(2+), Cu(2+) and Hg(2+), inorganic phosphate and pyrophosphate, low concentrations of SDS, guanidine hydrochloride and urea, organic solvents like dimethyl sulphoxide, dimethyl formamide and formamide but not by 3'- or 5'-mononucleotides. The studies on mode and mechanism of action showed that nuclease Rsn is an endonuclease and cleaves dsDNA through a single hit mechanism. The end products of both ssDNA and dsDNA hydrolysis were predominantly oligonucleotides ending in 3'-hydroxyl and 5'-phosphoryl termini. Moreover, the type of metal ion used did not influence the mode and mechanism of action of the enzyme.

Transient expression of Saccharomyces cerevisiae endo-exonuclease NUD1 gene increases the frequency of extrachromosomal homologous recombination in mouse Ltk- fibroblasts

Endo-exonucleases (EEs) are nucleolytic enzymes which have been shown to participate in the processes of DNA repair and recombination in eukaryotes. Recently, we have demonstrated that transient expression of Saccharomyces cerevisiae EE NUD1 gene in HeLa cells increased the resistance of the latter to ionizing radiation and cisplatin, suggesting the involvement of the NUD1 gene product in the recombination repair of double-strand breaks (DSB). Here, we report that transient expression of NUD1 results in up to 62% increase in the frequency of homologous recombination between two co-transfected linear plasmids in mouse Ltk- cells.

The unusual structures of the hot-regions flanking large-scale deletions in human mitochondrial DNA

Large-scale deletions of mitochondrial DNA (mtDNA) are common events that have been found to occur in human ageing and in patients with mitochondrial myopathies. The mechanisms by which these deletions occur remain unclear, but several mechanisms have been proposed, such as slipped-mispairing, illegitimate recombination, and oxidative reactions elicited by free radicals. In addition, the DNA topological stress and local DNA structures have been suggested as the important factors in eliciting the recombinational events. Upon examination of 128 breakpoints of human mtDNA deletions that have been published in the past 8 years, we found that these large-scale deletions often occur at some 'hot-regions'. We thus hypothesized that there exist unusual structures in these regions of human mtDNA that are important for eliciting the deletions. To test this hypothesis, we used PCR techniques to amplify the sequences of the so-called hot-regions and analysed the PCR products by two-dimensional gel electrophoresis. We found that the sequences of nucleotide position (np) 5221-5988, np 6928-7493, np 7901-8732 and np 15327-16228 exhibited retarded mobilities like bent DNA structures; np 5989-6750, np 13282-13653 and np 13282-14850 showed increased mobilities like anti-bent DNA structures. Moreover, except for the sequences of np 1175-1766 found in 12 S and 16 S rRNA genes exhibiting abnormal mobility like bent DNA structures, we did not observe significant mobility abnormalities in the np 499-5545 region where deletions rarely occurred. We thus conclude that these hot-regions assume some kinds of unusual DNA structures, which may render these regions more sensitive to the attack of free radicals or serve as recognition motifs for certain recombination machinery that is involved in the large-scale deletions of human mtDNA.

Characterization of an endonuclease activity which preferentially cleaves the G-rich immunoglobulin switch repeat sequences

B lymphocytes can alter selectively their immunoglobulin (Ig) isotype expressed by deletional rearrangement of the first active immunoglobulin heavy-chain (IgH) constant region (C mu) gene with one of six other constant region genes. Recombination breakpoints occur within highly repetitive "switch" (S) regions located upstream of each IgH constant region gene except C delta. Analysis of rearranged switch DNA junctions has not detected a consensus sequence, although the predominance of two pentamer motifs (TGGGG and TGAGC) at or near these breakpoints and throughout all murine S region sequences has led to their advocacy as the S recombination signals. In this paper, we describe the characterization and partial purification of a lymphoid-specific endo-nuclease activity which cleaves preferentially murine S region DNA. Enzyme activity selectively produced single- and double-stranded breaks at TGAGC and TGGG motifs within murine S mu and S alpha DNA. Rare cryptic cleavage sites were detected also within non-switch sequences, although cleavage intensities at these sites were reduced greatly, relative to consensus S region cleavages. Analogous activity was found in murine tissue extracts, although among the tissues assayed only spleen and thymus contained detectable activity. Subsequent biochemical characterization of this activity demonstrated that the responsible enzyme (Endo-SR) represented a previously unreported tissue-specific mammalian endonuclease. Endo-SR-specific activity could be enhanced by addition of Mg2+ or Ca2+ and inhibited by addition of Zn2+. Maximal specific activity was detected at pH 5.5 and sharply declined within +/- 0.5 pH units. In view of this enzyme's sequence- and tissue-specificity, we propose that Endo-SR is a strong candidate for an endonuclease activity associated with the switch recombination process.

A DNase from the trypanosomatid Crithidia fasciculata

We have purified to homogeneity a DNase from a Crithidia fasciculata crude mitochondrial lysate. The enzyme is present in two forms, either as a 32 kDa polypeptide or as a multimer containing the 32 kDa polypeptide in association with a 56 kDa polypeptide. Native molecular weight measurements indicate that these forms are a monomer and possibly an alpha 2 beta 2 tetramer, respectively. The monomeric and multimeric forms of the enzyme are similar in their catalytic activities. Both digest double-stranded DNA about twice as efficiently as single-stranded DNA. They introduce single-strand breaks into a supercoiled plasmid but do not efficiently make double-strand breaks. They degrade a linearized plasmid more efficiently than a nickel plasmid. Both enzymes degrade a 5'-32P-labeled double-stranded oligonucleotide to completion, with the 5'-terminal nucleotide ultimately being released as a 5'-mononucleotide. One difference between the monomeric and multimeric forms of the enzyme, demonstrated by a band shift assay, is that the multimeric form binds tightly to double-stranded DNA, possibly aggregating it.

Endonuclease G from mammalian nuclei is identical to the major endonuclease of mitochondria

Two Mg(2+)-dependent DNA endonucleases have been isolated from mammalian cells which have a strong preference to nick within long tracts of guanine residues in vitro. One endonuclease activity is mitochondrial (mt). The other endonuclease, called Endonuclease G, is associated with isolated nuclei, and is released when the nuclear chromatin is exposed to moderate ionic strength. Our laboratory has previously purified the mt endonuclease to near homogeneity from mitochondria of bovine heart and reported the enzyme to be a homodimer of a approximately 29 kDa polypeptide [Cummings, O. W. et al. (1987) J. Biol. Chem., 262, 2005-2015]. Although the purified mt endonuclease will extensively fragment M13 viral ssDNA and plasmid dsDNAs in vitro, the enzyme displays an unusually strong preference to nick within a (dG)12:(dC)12 sequence tract which resides just upstream from the origin of DNA replication in the mitochondrial genome. The nuclear Endonuclease G first identified from its selective targeting of several (dG)n:(dC)n tracts in vitro (where N = 3-29), was subsequently purified from calf thymus nuclei and shown to be a homodimer of a approximately 26-kDa polypeptide [Côté, J. et al. (1989) J. Biol. Chem., 264, 3301-3310]. In the present study, we find that Endonuclease G partially purified from calf thymus nuclei will extensively degrade both viral ss- and dsDNAs in vitro, and that the enzyme possesses biochemical properties and specificity for nucleotide sequences in DNA that are strongly related or identical to those of the mt endonuclease. These findings and the discovery of sequence identity between the proteins strengthen the conclusion that the nuclear Endonuclease G is the same enzyme as the mt endonuclease.

Single-strand-specific nucleases

Single-strand-specific nucleases, which act on single-stranded nucleic acids and single-stranded regions in double-stranded nucleic acids, are multifunctional enzymes and are ubiquitous in distribution. They find wide application as analytical tools in molecular biology research, although enzymes such as P1 nuclease are also used for production of flavor enhancers such as 5' IMP and 5' GMP. Because these enzymes are mainly used as analytical tools, very little attention was paid to aspects relating to their structure-function relationships. However, during the last few years considerable developments have taken place in this area. Single-strand-specific nucleases, their purification, characteristics, biological role, and applications have been reviewed.

Purification of Rad1 protein from Saccharomyces cerevisiae and further characterization of the Rad1/Rad10 endonuclease complex

The yeast recombination and repair proteins Rad1 and Rad10 associate with a 1:1 stoichiometry to form a stable complex with a relative molecular mass of 190 kDa. This complex, which has previously been shown to degrade single-stranded DNA endonucleolytically, also cleaves supercoiled duplex DNA molecules. In this reaction, supercoiled (form I) molecules are rapidly converted to nicked, relaxed (form II) molecules, presumably as a result of nicking at transient single-stranded regions in the supercoiled DNA. At high enzyme concentrations, there is a slow conversion of the form II molecules to linear (form III) molecules. The Rad1/Rad10 endonuclease does not preferentially cleave UV-irradiated DNA and has no detectable exonuclease activity. The nuclease activity of the Rad1/Rad10 complex is consistent with the predicted roles of the RAD1 and RAD10 genes of Saccharomyces cerevisiae in both the incision events of nucleotide excision repair and the removal of nonhomologous 3' single strands during intrachromosomal recombination between repeated sequences. In these pathways, the specificity and reactivity of the Rad1/Rad10 endonuclease will probably be modulated by further protein-protein interactions.

Yeast RNC1 encodes a chimeric protein, RhoNUC, with a human rho motif and deoxyribonuclease activity

The yeast Saccharomyces cerevisiae contains an endoexonuclease yNucR that has been implicated in both recombination and repair. We describe the isolation and characterization of the corresponding gene. Within the predicted N-terminal half of the protein there is extensive homology (approximately 50%) with human rho genes, which are related to the ras oncogene, particularly in the proposed GTP-binding region. The C-terminal region, which is related to the Escherichia coli recC protein, presumably encodes the endoexonuclease activity. The yNucR may thus represent a new class of GTP-binding proteins. Because of the chimeric nature of the polypeptide, this protein is renamed RhoNUC (rather than the original yNucR) and the gene is RNC1 for Rho-associated-NuClease. Over expression of the gene leads to altered cell growth and nuclear morphology. We propose that the gene plays an important role in cell development as well as DNA repair/recombination.

Purification and characterization of a mammalian endo-exonuclease

An endo-exonuclease has been purified from cultured monkey (CV-1) cells. The enzyme which was purified to near homogeneity to be a 65 kDa monomeric protein. The single-strand DNase activity is endonucleolytic and nonprocessive, whereas the double-strand DNase activity is exonucleolytic and processive. The enzyme was also found to have RNase activity using poly-rA as substrate. The pH optimum for ss-DNase is 8 and for ds-DNase it is 7.5. Both DNase activities require a divalent metal ion (Mg2+, Mn2+, Ca2+, Zn2+) for activity and exhibit the same kinetics of heat inactivation. The purified protein binds to and cleaves a synthetic Holliday junction substrate. The overall enzymatic characteristics of the mammalian protein are very similar to the putative recombination endo-exonucleases purified from Neurospora crassa, Aspergillus nidulans and Saccharomyces cerevisiae.

Nucleus-driven mutations of human mitochondrial DNA

Neuromuscular disorders due to abnormalities of mitochondrial energy supply have become an important area of human pathology. In particular, lesions of the mitochondrial genome (mtDNA), a small extra-nuclear chromosome which encodes 13 subunits of the respiratory chain complexes, are responsible for a steadily increasing number of neuromuscular syndromes. In addition to sporadic or maternally-inherited mutations, either qualitative or quantitative abnormalities of mtDNA can be transmitted as Mendelian traits, leading to well-defined mitochondrial encephalomyopathies. The latter are presumably caused by mutations in still unknown nucleus-encoded genes which deleteriously interact with the mitochondrial genome. These observations are of importance from both clinical and theoretical points of view, because they are the first examples of diseases produced by abnormalities of the nuclear control over mitochondrial biogenesis.

Mitochondrial endonuclease activity in the rat varies markedly among tissues in relation to the rate of tissue metabolism

Rat heart mitochondria contain a potent endonuclease activity that closely resembles the endonuclease of bovine and human heart mitochondria, and shows a striking preference for an evolutionarily conserved sequence that resides just upstream from the heavy (H)-strand origin of DNA replication (Ori H), (Low, R.L. et al. (1988) Nucleic Acids Res. 16, 6427-6425). This study reports that while the site-directed endonuclease is evident in the mt fractions of several rat organs, the levels of activity among them varies in an unexpected and marked fashion. There is nearly 200-times more of this endonuclease activity per mg of mt protein in the heart than in the liver (or spleen). Levels intermediate to those in heart and liver are found in the kidney and brain. The large variations in endonuclease activity do not correlate with reported rates of mtDNA turnover among tissues and are in contrast to the much smaller variations in levels of mtDNA and DNA polymerase-gamma activity. However, there may be some relationship between the amount of the endonuclease and the rate of oxidative phosphorylation.

Alteration of a nuclease in Fanconi anemia

Fanconi anemia is a cancer-prone disease characterized by progressive loss of blood cells, skeletal defects and stunted growth. Studies of a nuclease acting on double-stranded DNA have revealed an enzyme alteration in cells derived from Fanconi patients. A particulate fraction isolated from cultured human lymphoblasts and fibroblasts was solubilized with detergent and subjected to isoelectric focusing. Nuclease activity observed in four normal cell lines bands in a pH gradient with a pI of 6.3. Four cell lines belonging to complementation group A exhibit an increase in the pI of that nuclease to 6.8. These observations provide a new diagnostic for this disorder. Analysis of this enzyme in tetraploid cultures derived from fusion of normal and Fanconi cells suggest that the normal phenotype is dominant. That observation supports the hypothesis that the Fanconi A gene is required for modification of the nuclease pI. Definition of the molecular basis of this enzyme alteration should provide insight into the primary genetic lesion in this disorder.

The split-end model for homologous recombination at double-strand breaks and at Chi

In recent years two different styles of model for homologous recombination have been discussed, depending on whether or not the recombination event occurs in the vicinity of a double-strand break in DNA. The models of Holliday and Meselson and Radding exemplify those that do not involve a break whereas the model of Szostak et al is taken as an example of those that do. Recent advances in understanding a prototypic recombination system thought to promote exchange distant from DNA ends, at Chi sites, suggest a mechanism of initiation neither like Holliday/Meselson-Radding nor like Szostak et al. In those models, only one strand of DNA may invade a homologous DNA molecule. We propose a model for Chi in which exonuclease degrades DNA from a double-strand break to the Chi site; the exonuclease is converted into a helicase upon interaction with Chi; unwinding produces a recombinagenic split-end, and both 3'- and 5'-ending strands at the split-end are capable of invading a homologue. Different genetic consequences are proposed to result from invasion by each. We review evidence supporting the split-end model and suggest its application in at least some cases previously considered to proceed via the Meselson/Radding model and by the double-strand-break repair model of Szostak et al.

Different mechanisms inferred from sequences of human mitochondrial DNA deletions in ocular myopathies

We have sequenced the deletion borders of the muscle mitochondrial DNA from 24 patients with heteroplasmic deletions. The length of these deletions varies from 2.310 bp to 8.476 bp and spans from position 5.786 to 15.925 of the human mitochondrial genome preserving the heavy chain and light chain origins of replication. 12 cases are common deletions identical to the mutation already described by other workers and characterized by 13 bp repeats at the deletion boundaries, one of these repeats being retained during the deletion process. The other cases (10 out of 12) have shown deletions which have not been previously described. All these deletions are located in the H strand DNA region which is potentially single stranded during mitochondrial DNA replication. In two cases, the retained Adenosine from repeat closed to the heavy strand origin of replication would indicate slippage mispairing. Furthermore in one patient two mt DNA molecules have been cloned and their sequences showed the difference of four nucleotides in the breakpoint of the deletion, possibly dued to slippage mispairing. Taken together our results suggest that deletions occur either by slippage mispairing or by internal recombination at the direct repeat level. They also suggest that different mechanisms account for the deletions since similarly located deletions may display different motives at the boundaries including the absence of any direct repeat.

Substrate specificity and kinetics of degradation of antisense oligonucleotides by a 3' exonuclease in plasma

The pathways of degradation of oligodeoxynucleotides in plasma from several mammalian species, including human, were investigated. In all cases, hydrolysis occurred exclusively by a 3' to 5' exonucleolytic activity. Human, mouse, and rat plasma degraded oligonucleotides in this fashion at comparable rates, whereas rabbit plasma was severalfold more active. Single-stranded oligonucleotides were more susceptible to hydrolysis than double-stranded oligonucleotides. The rate of hydrolysis was sequence dependent: 3' pyrimidine nucleotides were cleaved more rapidly than 3' purines. The Km and Vmax values for an oligonucleotide 15-mer with the sequence TAGCACCATGGTTTC in human plasma were 50 microM and 4.5 microM/min, respectively. Substitution of the 3'-terminal phosphodiester internucleoside linkage with a phosphotriester rendered this substrate completely resistant to hydrolysis, showing that the enzyme is a pure 3' to 5' exonuclease and that there are no other nucleolytic activities in plasma. Modification at this position is required to inhibit rapid nuclease degradation of antisense compounds in vivo and in tissue culture systems requiring serum.

Direct repeats in the non-coding region of rabbit mitochondrial DNA. Involvement in the generation of intra- and inter-individual heterogeneity

In rabbit we observed heteroplasmy at an exceptionally high level, the heterogeneity occurring within the non-coding region of the DNA. Mitochondrial DNA (mt DNA) was cloned in pBR322 and the nucleotide sequence analysis of an EcoRI-Hind III fragment encompassing the non-coding region revealed that although there are common features with other mammalian mtDNAs (termed large central-conserved-sequence block, conserved-sequence blocks 1, 2 and 3 and termination-associated elements) the non-coding region shows an unusual organization; two stretches of tandem repeats of 20 bp and 153 bp are present in a part containing the origin of H-strand replication (OH) and probably the promoters for transcription as judged from other vertebrates. The long repeats are located between tRNA(Phe) and conserved sequence block 3 and the short repeats are located between conserved sequence blocks 1 and 2. When cloned in Escherichia coli (recA or recBC sbcb) DNA fragments containing the short repeats show length differences corresponding to various copy numbers of repeats. Electrophoretic analysis of the appropriate restriction fragments of rabbit mtDNA reveals extended intra- and inter-individual length heterogeneity. Both sets of repeats are involved in the generation of heterogeneity and are present in variable copy numbers from one mtDNA molecule to another. Moreover, rearrangement of the motives of the short repeat are observed to different extents in the mtDNA from one animal to another. The occurrence, maintenance and possible involvement of these repeated sequences, capable of forming stable secondary structures, are discussed in relation to their location in the region of control signals.

A mitochondrial nuclease is modified in Drosophila mutants (mus308) that are hypersensitive to DNA crosslinking agents

The mus308 mutants of Drosophila have previously been demonstrated to be defective in an enzyme that is designated Nuclease 3 (Boyd et al. 1990b). In this study that enzyme is shown to be present in mitochondria of both wild-type flies and embryos. Since the mus308 mutants are hypersensitive to DNA crosslinking agents. Nuclease 3 is potentially required for resistance of the mitochondrial genome to such agents. In support of this hypothesis, electron microscopic studies of mus308 mutant flies that had been exposed to nitrogen mustard revealed an increased frequency of mitochondrial abnormalities. Further investigation of the defect at the enzymological level revealed that the mutants possess a new nuclease activity that is apparently a modified form of the wild-type protein. In the earlier study, enzyme extracts from mus308 mutants were found to lack an enzyme with a pI of approximately 6.2. More precisely defined assay conditions in this study revealed the appearance of a new nuclease activity with a higher pI in extracts from mutants. This observation, together with the finding that only the normal enzyme form is present in heterozygous individuals, supports the hypothesis that the mus308 locus is not the structural gene for the enzyme. Rather, the mus308 gene product is necessary for Nuclease 3 to assume the lower pI. Nuclease 3 has been partially purified and characterized from wild-type embryos. Its activity is stimulated by Mg++ and ATP. Optimum activity is found at a pH of 5.5 and a NaCl concentration of 50-100 mM. Nuclease 3 exhibits a temperature optimum of 42 degrees C and is insensitive to N-ethylmaleimide.(ABSTRACT TRUNCATED AT 250 WORDS)

Mammalian mitochondrial endonuclease activities specific for ultraviolet-irradiated DNA

Mitochondrial forms of uracil DNA glycosylase and UV endonuclease have been purified and characterized from the mouse plasmacytoma cell line, MPC-11. As in other cell types, the mitochondrial uracil DNA glycosylase has properties very similar to those of the nuclear enzyme, although in this case the mitochondrial activity was also distinguishable by extreme sensitivity to dilution. Three mitochondrial UV endonuclease activities are also similar to nuclear enzymes; however, the relative amounts of these enzyme activities in the mitochondria is significantly different from that in the nucleus. In particular, mitochondria contain a much higher proportion of an activity analogous to UV endonuclease III. Nuclear UV endonuclease III activity is absent from XP group D fibroblasts and XP group D lymphoblasts have reduced, but detectable levels of the mitochondrial form of this enzyme. This residual activity differs in its properties from the normal mitochondrial form of UV endonuclease III, however. The presence of these enzyme activities which function in base excision repair suggests that such DNA repair occurs in mitochondria. Alternatively, these enzymes might act to mark damaged mitochondrial genomes for subsequent degradation.

Neurospora endo-exonuclease is immunochemically related to the recC gene product of Escherichia coli

Immunochemical cross-reaction between the endo-exonuclease of Neurospora crassa, an enzyme previously implicated in recombination and recombinational DNA repair, and the recC-encoded polypeptide of Escherichia coli has been detected by immunoblotting extracts of strains of E. coli having a deletion that includes the recBCD genes but carrying multicopy plasmids bearing all three of the recBCD genes or only one or two of these genes. It was predicted that homology would also be found at the amino acid sequence level between the recC polypeptide and both nuclear and mitochondrial endo-exonucleases of Saccharomyces cerevisiae, which cross-react with antibodies raised to the N. crassa endo-exonuclease. Since the gene for the S. cerevisiae mitochondrial enzyme, NUC1, has been cloned and sequenced and the predicted amino acid sequence is known, this sequence was aligned with the predicted amino acid sequence of the recC polypeptide. Extensive homology was found by aligning 306 of the 329 amino acids of the yeast mitochondrial nuclease sequence with the carboxy-terminal one-quarter of the amino acid sequence of the recC polypeptide.

Variation in salmonid mitochondrial DNA: evolutionary constraints and mechanisms of substitution

Sequence comparisons were made from 2214 bp of mitochondrial DNA cloned from six Pacific salmonid species. These sequences include the genes for ATPase subunit 6, cytochrome oxidase subunit 3, NADH dehydrogenase subunit 3, NADH dehydrogenase subunit 4L, tRNA(GLY), and tRNA(ARG). Variation is found at 338 silent and 12 nonsilent positions of protein coding genes and 10 positions in the two tRNA sequences. A single 3-bp length difference was also detected. In all pairwise comparisons the sequence divergence observed in the fragment was higher than that previously predicted by restriction enzyme analysis of the entire molecule. The inferred evolutionary relationship of these species is consistent between methods. The distribution of silent variation shows a complex pattern with greatly reduced variation at the junctions of genes. The variation in the tRNA sequences is concentrated in the DHU loop. The close relationship of these species and extensive sequence analyzed allows for an analysis of the spectrum of substitutions that includes the frequencies of all 12 possible substitutions. The observed spectrum of substitutions is related to potential pathways of spontaneous substitution. The salmonid sequences show an extremely high ratio of silent to replacement substitutions. In addition the amino acid sequences of the four proteins coded in this fragment show a consistently high level of identity with the Xenopus sequences. Taken together these data are consistent with a slower rate of amino acid substitution among the cold-blooded vertebrates when compared to mammals.

Purification and properties of an endonuclease endogenous to rat-liver nuclei

An endonuclease endogenous to rat-liver nuclei has been purified by a series of chromatographic procedures and finally by isoelectric focusing (IEF) electrophoresis. The nuclease fraction prepared by the IEF electrophoresis (IEF fraction) showed a pI value of 5.7 and migrated as a single band to a molecular weight position of 46,000 on an SDS-polyacrylamide gel. The activity for single-stranded DNA was enhanced by 10 mM MgCl2 and/or by 5-15 mM MgCl2 in the presence of 2 mM CaCl2 (an optimum pH, 7.0), but was lowered by CaCl2 alone and inhibited strongly by ZnCl2 or MnCl2. The activity for duplex DNA was rather low, although an optimum condition was 10 mM MgCl2. In fact, even under this condition, the activity was about 40% lower than that for single-stranded DNA. Moreover, the IEF fraction formed single-strand nicks much more rapidly than double-strand cuts in pBR322 DNA, and preferentially produced deoxyadenosine 5'-monophosphate termini in the DNA. In addition, RNAase activity was also detected in this fraction.

An autosomal dominant disorder with multiple deletions of mitochondrial DNA starting at the D-loop region

Deletions of muscle mitochondrial DNA (mtDNA) have recently been found in patients with mitochondrial myopathy. However, as most of the described cases were sporadic, and individual deletions involved different portions of mtDNA, the mechanism(s) producing the molecular lesions, as well as their mode of transmission, remain unclear. By studying families with mtDNA heteroplasmy, valuable information can be obtained about the role of inheritable factors in the pathogenesis of these disorders. We have studied four members of a family with autosomal dominant mitochondrial myopathy. Multiple deletions, involving the same portion of muscle mtDNA, were identified in all patients. Sequence analysis of the mutant mtDNAs, performed after DNA amplification by the polymerase-chain reaction showed that all the deletions start within a 12-nucleotide stretch at the 5' end of the D-loop region, a site of active communication between the nucleus and the mtDNA. The data indicate that a mutation of a nuclear-coded protein can destroy the integrity of the mitochondrial genome in a specific, heritable way.

A direct repeat is a hotspot for large-scale deletion of human mitochondrial DNA

Kearns-Sayre syndrome (KSS) and progressive external ophthalmoplegia (PEO) are related neuromuscular disorders characterized by ocular myopathy and ophthalmoplegia. Almost all patients with KSS and about half with PEO harbor large deletions in their mitochondrial genomes. The deletions differ in both size and location, except for one, 5 kilobases long, that is found in more than one-third of all patients examined. This common deletion was found to be flanked by a perfect 13-base pair direct repeat in the normal mitochondrial genome. This result suggests that homologous recombination deleting large regions of intervening mitochondrial DNA, which previously had been observed only in lower eukaryotes and plants, operates in mammalian mitochondrial genomes as well, and is at least one cause of the deletions found in these two related mitochondrial myopathies.

Purification and properties of a magnesium-dependent endodeoxyribonuclease endogenous to rat-liver nuclei

An Mg2+-dependent endonuclease has been purified from a 0.6 M NaCl extract of rat-liver nuclei by a series of chromatographic procedures and finally by isoelectric focusing (IEF) electrophoresis. The nuclease fraction prepared by the IEF electrophoresis (IEF fraction) was shown to have a pI value of 7.1 and to migrate as a single band to a molecular-weight position of 36,500 on SDS-polyacrylamide gel. The IEF fraction was subjected to a sedimentation analysis. In a hypotonic buffer (10 mM Tris), the nuclease activity sedimented to have an S value of 4.1 S. However, in an isotonic buffer (0.15 M NaCl), this fraction exhibited two activity peaks of 2.8 and 4.3 S. In a hypertonic buffer (0.3 M NaCl), almost all of the nuclease activity sedimented at 2.7-2.8 S. In this connection, values of 2.8 and 4.3 S were determined to correspond to molecular weights of about 36,000 and 70,000, respectively. Thus, an Mg2+-dependent endonuclease, endogenous to rat-liver nuclei, has been inferred to exist in the reversible form of a monomer/homodimer as its native state. Moreover, the IEF fraction formed single-strand nicks more rapidly than double-strand cuts in pBR322 DNA, and preferentially produced deoxyguanosine 5'-monophosphate termini in the DNA at an early incubation time. In addition, RNAase activity was not detected in this fraction.