Dynamic Compartmentalization of Base Excision Repair Proteins in Response to Nuclear and Mitochondrial Oxidative Stress

DNAs harbored in both nuclei and mitochondria of eukaryotic cells are subject to continuous oxidative damage resulting from normal metabolic activities or environmental insults. Oxidative DNA damage is primarily reversed by the base excision repair (BER) pathway, initiated by N-glycosylase apurinic/apyrimidinic (AP) lyase proteins. To execute an appropriate repair response, BER components must be distributed to accommodate levels of genotoxic stress that may vary considerably between nuclei and mitochondria, depending on the growth state and stress environment of the cell. Numerous examples exist where cells respond to signals, resulting in relocalization of proteins involved in key biological transactions. To address whether such dynamic localization contributes to efficient organelle-specific DNA repair, we determined the intracellular localization of the Saccharomyces cerevisiae N-glycosylase/AP lyases, Ntg1 and Ntg2, in response to nuclear and mitochondrial oxidative stress. Fluorescence microscopy revealed that Ntg1 is differentially localized to nuclei and mitochondria, likely in response to the oxidative DNA damage status of the organelle. Sumoylation is associated with targeting of Ntg1 to nuclei containing oxidative DNA damage. These studies demonstrate that trafficking of DNA repair proteins to organelles containing high levels of oxidative DNA damage may be a central point for regulating BER in response to oxidative stress.     

Overexpression of enzymes that repair endogenous damage to DNA.

A significant contribution to human mutagenesis and carcinogenesis may come from DNA damage of endogenous, rather than exogenous, origin. Efficient repair mechanisms have evolved to cope with this. The main repair pathway involved in repair of endogenous damage is DNA base excision repair. In addition, an important contribution is given by O6-alkylguanine DNA alkyltranferase, that repairs specifically the miscoding base O6-alkylguanine. In recent years, several attempts have been carried out to enhance the efficiency of repair of endogenous damage by overexpressing in mammalian cells single enzymatic activities. In some cases (e.g. O6-alkylguanine DNA alkyltransferase or yeast AP endonuclease) this approach has been successful in improving cellular protection from endogenous and exogenous mutagens, while overexpression of other enzymatic activities (e.g. alkyl N-purine glycosylase or DNA polymerase beta) were detrimental and even produced a genome instability phenotype. The reasons for these different outcomes are analyzed and alternative enzymatic activities whose overexpression may improve the efficiency of repair of endogenous damage in human cells are proposed.     

Structural aspects of DNA repair: the role of restricted diffusion

DNA repair and protection processes impose arduous demands upon cellular systems. The high-fidelity recombinational repair pathway entails a rapid genome-wide search for sequence homology. The efficiency of this transaction is intriguing in light of the uniquely adverse diffusion traits of the involved species. DNA protection in cells exposed to continuous stress or prolonged starvation is equally enigmatic, because the ability of such cells to deploy energy-dependent enzymatic repair processes is hampered as a result of progressive perturbation of the intracellular energy balance. DNA repair in radio-resistant bacteria, which involves accurate chromosome reconstruction from multiple fragments, is similarly associated with apparently insurmountable logistical obstacles. The studies reviewed here imply that the mechanisms deployed to overcome these intrinsic hurdles have a basic common denominator. In all these cases, condensed and ordered chromatin assemblies are formed, within which molecular diffusion is restricted and confined. Restricted diffusion thus appears as a general strategy that is exploited by nature to facilitate homologous search, to promote energy-independent DNA protection through physical DNA sequestration and attenuated accessibility to damaging agents, and to enable error-free repair of multiple double-strand DNA breaks.     

Repair of DNA damage in a mitochondrial lysate of Xenopus laevis oocytes.

We examined DNA repair activities of a mitochondrial lysate derived from Xenopus laevis oocytes. Plasmid DNA, exposed to HCl, H2O2 or UV light, was used as the substrate for the in vitro repair reaction. DNA synthesis in the lysate was stimulated 2-8-fold by such lesions, indicating the presence of excision repair activities. This repair DNA synthesis was not affected by aphidicolin, but was sensitive to N-ethylmaleimide. Thus the mitochondrial DNA polymerase, i.e., pol gamma is indeed involved in the reaction. Actual repair of the depurinated DNA was demonstrated by using the polymerase chain reaction (PCR), where the amount of the amplified DNA fragment increased significantly if the depurinated template was incubated in the lysate prior to the PCR. UV-irradiated DNA, on the other hand, restored its ability as a PCR template only if the repair reaction was carried out under the light. Therefore, in this system, UV-induced damage is repaired mainly by photoreactivation. These results show that mitochondria of Xenopus oocytes possess excision repair as well as photolyase activities, and that the in vitro repair system described here should be useful for further molecular characterization of such DNA repair machinery.     

DNA methylation reprogramming and DNA repair in the mouse zygote

Here, we summarize current knowledge about epigenetic reprogramming during mammalian preimplantation development, as well as the potential mechanisms driving these processes. We will particularly focus on changes taking place in the zygote, where the paternally derived DNA and chromatin undergo the most striking alterations, such as replacement of protamines by histones, histone modifications and active DNA demethylation. The putative mechanisms of active paternal DNA demethylation have been studied for over a decade, accumulating a lot of circumstantial evidence for enzymatic activities provided by the oocyte, protection of the maternal genome against such activities and possible involvement of DNA repair. We will discuss the various facets of dynamic epigenetic changes related to DNA methylation with an emphasis on the putative involvement of DNA repair in DNA demethylation.     

Isolation and characterization of a DNA primase from human mitochondria

A family of enzymatic activities isolated from human mitochondria is capable of initiating DNA replication on single-stranded templates. The principal enzymes include at least a primase and DNA polymerase gamma and require that rNTPs as well as dNTPs be present in the reaction mixture. Poly(dC) and poly(dT), as well as M13 phage DNA, are excellent templates for the primase activity. A single-stranded DNA containing the cloned origin of mitochondrial light-strand synthesis can be a more efficient template than M13 phage DNA alone. Primase and DNA polymerase activities were separated from each other by sedimentation in a glycerol density gradient. Using M13 phage DNA as template, these mitochondrial enzymes synthesize RNA primers that are 9 to 12 nucleotides in size and are covalently linked to nascent DNA. The formation of primers appears to be the rate-limiting step in the replication process. Replication of M13 DNA is sensitive to N-ethylmaleimide and dideoxynucleoside triphosphates, but insensitive to rifampicin, alpha-amanitin, and aphidicolin.     

DNA double-strand break repair from head to tail

DNA double-strand break repair is a complex process that requires multiple enzymatic and structural activities to rejoin or repair the broken DNA ends using one of several repair pathways. These enzymatic and structural activities include end detection, end processing and alignment of DNA ends. Recent structural and functional studies of the DNA double-strand break repair factors Mre11/Rad50, Ku70/80 and Xrcc4 show how these enzymes combine and assemble both enzymatic and structural activities in DNA double-strand break repair.     

Mutagenesis in Oocytes of DROSOPHILA MELANOGASTER. I. Scheduled Synthesis of Nuclear and Mitochondrial DNA and Unscheduled DNA Synthesis

As a model system for studying mutagenesis, the oocyte of Drosophila melanogaster has exhibited considerable complexity. Very few experiments have been conducted on the effect of exposing oocytes to chemical mutagens, presumably due to their lower mutational response relative to sperm and spermatids. This lower response may be due either to a change in probability of mutation induction per adduct due to a change in the type of DNA repair or to a lower dose of the mutagen to the female germ line. To study molecular dosimetry and DNA repair in the oocyte, the large number of intracellular constituents (mtDNA, RNA, nucleic acid precursors and large quantities of proteins and lipids) must be separated from nuclear DNA. In this paper we present results showing reliable separation of such molecules enabling us to detect scheduled nuclear and mitochondrial DNA synthesis. We also, by understanding the precise timing of such events, can detect unscheduled DNA synthesis (UDS) as a measure of DNA repair. Furthermore, by comparing the UDS results in a repair competent (Ore-R) vs. a repair deficient (mei-9^L1 ) strain, we have shown the oocyte capable of DNA repair after treatment with ethyl methanesulfonate (EMS). We conclude that the important determinant of mutation induction in oocytes after treatment with EMS is the time interval between DNA alkylation and DNA synthesis after fertilization, i.e., the interruption of continuous DNA repair.     

DNA polymerases β and λ and their roles in cell

Among the set of mammalian DNA polymerases, DNA polymerases belonging to the X and Y families have a special place. The majority of these enzymes are involved in repair, including base excision repair and non-homologous end joining. Some of them play a crucial role during the specific process which is referred to as translesion synthesis (TLS). TLS intends for the cell surviving during the replication of damaged DNA templates. Additionally, specific activities of TLS-polymerases have to be useful for repair of double-stranded clustered lesions: if the synthesis is proceeded via base excision repair process, the role of DNA polymerases β or λ will be important. In this review we discussed the biochemical properties and functional relevance of X family DNA polymerases β and λ.     

XRCC1 and DNA strand break repair

DNA single-strand breaks can arise indirectly, as normal intermediates of DNA base excision repair, or directly from damage to deoxyribose. Because single-strand breaks are induced by endogenous reactive molecules such as reactive oxygen species, these lesions pose a continuous threat to genetic integrity. XRCC1 protein plays a major role in facilitating the repair of single-strand breaks in mammalian cells, via an ability to interact with multiple enzymatic components of repair reactions. Here, the protein-protein interactions facilitated by XRCC1, and the repair processes in which these interactions operate, are reviewed. Models for the repair of single-strand breaks during base excision repair and at direct breaks are presented.     

CRISPR–Cas9-mediated nuclear transport and genomic integration of nanostructured genes in human primary cells

DNA nanostructures are a promising tool to deliver molecular payloads to cells. DNA origami structures, where long single-stranded DNA is folded into a compact nanostructure, present an attractive approach to package genes; however, effective delivery of genetic material into cell nuclei has remained a critical challenge. Here, we describe the use of DNA nanostructures encoding an intact human gene and a fluorescent protein encoding gene as compact templates for gene integration by CRISPR-mediated homology-directed repair (HDR). Our design includes CRISPR–Cas9 ribonucleoprotein binding sites on DNA nanostructures to increase shuttling into the nucleus. We demonstrate efficient shuttling and genomic integration of DNA nanostructures using transfection and electroporation. These nanostructured templates display lower toxicity and higher insertion efficiency compared to unstructured double-stranded DNA templates in human primary cells. Furthermore, our study validates virus-like particles as an efficient method of DNA nanostructure delivery, opening the possibility of delivering nanostructures in vivo to specific cell types. Together, these results provide new approaches to gene delivery with DNA nanostructures and establish their use as HDR templates, exploiting both their design features and their ability to encode genetic information. This work also opens a door to translate other DNA nanodevice functions, such as biosensing, into cell nuclei.     

DNA polymerases beta and lambda, and their roles in the DNA replication and repair

One of the key stages of life of a cell is genome duplication. The main enzymes which lead this process are DNA-dependent DNA polymerases. At the moment, 19 DNA polymerases with striking properties are listed in the eukaryotic cells. Mitochondrial DNA polymerase gamma from A family and most of the nuclear enzymes from B family are high fidelity DNA polymerases which are participate in genome DNA replication process as well as in DNA repair. Among the other 1 5 proteins, the D N A polymerases belonging to the X and Y families have a special place. They participate in a different repair processes such as base excision repair and non-homologous end joining. Moreover, some of them play a specific role in the replication of the damaged DNA templates. This process is referred as translesion synthesis or TLS. The DNA polymerases beta and lambda members of X family are enclosed in polyfunctional enzymes, and their properties and functions will be discussed in this review.     

The DNA damage response: making it safe to play with knives

Damage to our genetic material is an ongoing threat to both our ability to faithfully transmit genetic information to our offspring as well as our own survival. To respond to these threats, eukaryotes have evolved the DNA damage response (DDR). The DDR is a complex signal transduction pathway that has the ability to sense DNA damage and transduce this information to the cell to influence cellular responses to DNA damage. Cells possess an arsenal of enzymatic tools capable of remodeling and repairing DNA; however, their activities must be tightly regulated in a temporal, spatial, and DNA lesion-appropriate fashion to optimize repair and prevent unnecessary and potentially deleterious alterations in the structure of DNA during normal cellular processes. This review will focus on how the DDR controls DNA repair and the phenotypic consequences of defects in these critical regulatory functions in mammals.     

DNA template requirements for human mismatch repair in vitro

The human mismatch repair pathway is competent to correct DNA mismatches in a strand-specific manner. At present, only nicks are known to support strand discrimination, although the DNA end within the active site of replication is often proposed to serve this role. We therefore tested the competence of DNA ends or gaps to direct mismatch correction. Eight G.T templates were constructed which contained a nick or gap of 4, 28, or approximately 200 nucleotides situated approximately 330 bp away in either orientation. A competition was established in which the mismatch repair machinery had to compete with gap-filling replication and ligation activities for access to the strand discontinuity. Gaps of 4 or 28 nucleotides were the most effective strand discrimination signals for mismatch repair, whereas double strand breaks did not direct repair to either strand. To define the minimal spatial requirements for access to either the strand signal or mismatch site, the nicked templates were linearized close to either site and assayed. As few as 14 bp beyond the nick supported mismatch excision, although repair synthesis failed using 5'-nicked templates. Finally, asymmetric G.T templates with a remote nick and a nearby DNA end were repaired efficiently.     

Co-ordination of base excision repair and genome stability

Base excision repair (BER) is a major DNA repair pathway employed in mammalian cells that is required to maintain genome stability, thus preventing several human diseases, such as ageing, neurodegenerative diseases and cancer. This is achieved through the repair of damaged DNA bases, sites of base loss and single strand breaks of varying complexity that are continuously induced endogenously or via exogenous mutagens. Whilst the enzymes involved in BER are now well known and characterised, the role of the co-ordination of BER enzymatic activities in the cellular response to DNA damage and the mechanisms regulating this process are only now being revealed. Post-translational modifications of BER proteins, including ubiquitylation and phosphorylation, are increasingly being identified as key processes that regulate BER. In this review we will summarise recent evidence discovering novel mechanisms that are involved in maintaining genome stability by regulation of the key BER proteins in response to DNA damage.     

Base excision repair apurinic/apyrimidinic endonucleases in apicomplexan parasite Toxoplasma gondii

DNA repair is essential for cell viability and proliferation. In addition to reactive oxygen produced as a byproduct of their own metabolism, intracellular parasites also have to manage oxidative stress generated as a defense mechanism by the host. The spontaneous loss of DNA bases due to hydrolysis and oxidative DNA damage in intracellular parasites is great, but little is known about the type of DNA repair machineries that exist in these early-branching eukaryotes. However, it is clear, processes similar to DNA base excision repair (BER) must exist to rectify spontaneous and host-mediated damage in Toxoplasma gondii. Here we report that T. gondii, an opportunistic protozoan pathogen, possesses two apurinic/apyrimidinic (AP) endonucleases that function in DNA BER. We characterize the enzymatic activities of Toxoplasma exonuclease III (ExoIII, or Ape1) and endonuclease IV (EndoIV, or Apn1), designated TgAPE and TgAPN, respectively. Over-expression of TgAPN in Toxoplasma conferred protection from DNA damage, and viable knockouts of TgAPN were not obtainable. We generated an inducible TgAPN knockdown mutant using a ligand-controlled destabilization domain to establish that TgAPN is critical for Toxoplasma to recover from DNA damage. The importance of TgAPN and the fact that humans lack any observable APN family activity highlights TgAPN as a promising candidate for drug development to treat toxoplasmosis.