Electron microscopy of DNA excision repair patches produced by human cell extracts

Graphene specimen support technique for low voltage STEM imaging

The scanning transmission electron microscopy (STEM) mode of today's field emission scanning electron microscopes enables sub-nanometer resolution imaging. Graphene is a single-atom thick, electrically conductive material, making it an excellent specimen support for the low voltage STEM imaging of nanometer-sized objects such as viruses. Here we present low voltage STEM images of bacteriophage T4 recorded on highly cleaned graphene films. The results show that ultrathin graphene support films markedly improve image signal at low accelerating voltages. Staining with a low atomic number methylamine vanadate stain combined with the graphene support film enables the clear visualization of the fine structure of the T4 tail by the low voltage STEM technique. Despite the advantages of graphene support films, difficulties are often encountered in placing hydrophilic biological samples on hydrophobic graphene electron microscopy grids. We employed a spin sedimentation sample loading method to overcome this problem.

Quality control by DNA repair

Faithful maintenance of the genome is crucial to the individual and to species. DNA damage arises from both endogenous sources such as water and oxygen and exogenous sources such as sunlight and tobacco smoke. In human cells, base alterations are generally removed by excision repair pathways that counteract the mutagenic effects of DNA lesions. This serves to maintain the integrity of the genetic information, although not all of the pathways are absolutely error-free. In some cases, DNA damage is not repaired but is instead bypassed by specialized DNA polymerases.

Differential human nucleotide excision repair of paired and mispaired cisplatin-DNA adducts

In order to understand the action of the chemotherapeutic drug cisplatin, it is necessary to determine why some types of cisplatin-DNA intrastrand crosslinks are repaired better than others. Using cell extracts and circular duplex DNA, we compared nucleotide excision repair of uniquely placed 1,2-GG, 1,2-AG, and 1,3-GTG cisplatin-crosslinks, and a 2-acetylaminofluorene lesion. The 1,3 crosslink and the acetylaminofluorene lesion were repaired by normal cell extracts approximately 15-20 fold better than the 1,2 crosslinks. No evidence was found for selective shielding of 1,2 cisplatin crosslinks from repair by cellular proteins. Fractionation of cell extracts to remove putative shielding proteins did not improve repair of the 1,2-GG crosslink, and cell extracts did not selectively inhibit access of UvrABC incision nuclease to 1,2-GG crosslinks. The poorer repair of 1,2 crosslinks in comparison to the 1,3 crosslink is more likely a consequence of different structural alterations of the DNA helix. In support of this, a 1,2-GG-cisplatin crosslink was much better repaired when it was opposite one or two non-complementary thymines. Extracts from cells defective in the hMutSalpha mismatch binding activity also showed preferential repair of the 1,3 crosslink over the 1,2 crosslink, and increased repair of the 1,2 adduct when opposite thymines, showing that hMutSalphais not involved in the differential NER of these substrates in vitro. Mismatched cisplatin adducts could arise by translesion DNA synthesis, and improved repair of such adducts could promote cisplatin-induced mutagenesis in some cases.

Preferential repair incision of cross-links versus monoadducts in psoralen-damaged plasmid DNA by human cell-free extracts

Upon UVA irradiation psoralens covalently bind to DNA as monoadduct and interstrand crosslink. Psoralen photoadducts are processed via an excision repair reaction that has been reproduced in vitro with transcriptionnally active cell-free extracts. A derived in vitro assay that allows direct quantification of the incised sites has been set up and used to compare the efficiency of the incision reaction on monoadducts and interstrand cross-links. The incision reaction was performed with HeLa cell-free extracts on angelicin or 8-methoxypsoralen (8-MOP)-modified plasmid DNA substrates carrying known amounts of mono- and biadducts, within various relative ratios. In the case of 8-MOP modified plasmids consisting in a mixture of mono- and biadducts on the same DNA molecule, the incision signal was mainly due to the presence of interstrand cross-links. The extent of incision was linear with the number of cross-links up to about 4 cross-links per plasmid and then reached a plateau. The sensitivity of incision defined as the increase of incision by 2-fold over the background level corresponded to about 1 cross-link per plasmid molecule, and about 7% of the total cross-links were repaired under our assay conditions. The incision activity on angelicin monoadducts yielded only 27% when compared to that on 8-MOP cross-links. Furthermore, 8-MOP cross-links lowered the incision extent of angelicin monoadducts when the two photoadducts were present on distinct plasmid DNA molecules. These data are in line with the more rapid excision of psoralen interstrand cross-links vs monoadducts observed in vivo.

Repair of abasic sites by mammalian cell extracts

Hamster cell extracts that perform repair synthesis on covalently closed circular DNA containing pyrimidine dimers, were used to study the repair of apurinic/apyrimidinic (AP) sites and methoxyamine (MX)-modified AP sites. Plasmid molecules were heat-treated at pH 5 and incubated with MX when required. The amount of damage introduced ranged from 0.2 to 0.9 AP sites/kb. Extracts were prepared from the Chinese hamster ovary CHO-9 cell line and from its derivative, 43-3B clone which is mutated in the nucleotide excision repair (NER) ERCC1 gene. AP and MX-AP sites stimulated repair synthesis by CHO-9 cell extracts. The level of synthesis correlated with the number of lesions and was of similar magnitude to the repair stimulated by 4.3 u.v. photoproducts/kb. Repair of AP and MX-AP sites was faster than the repair of u.v. damage and was independent of ERCC1 gene product. The high level of repair replication was due to a very efficient and rapid incision of plasmids carrying AP or MX-AP sites, performed by abundant AP endonucleases present in the extract. The calculated average repair patch sizes were: 7 nucleotides per AP site; 10 nucleotides per MX-AP site; 28 nucleotides per (6-4) u.v. photoproduct or cyclobutane pyrimidine dimer. The data indicate that AP and MX-AP sites are very efficiently repaired by base-excision repair in mammalian cells and suggest that MX-AP sites may also be processed via alternative repair mechanisms.

Properties of damage-dependent DNA incision by nucleotide excision repair in human cell-free extracts

Nucleotide excision repair (NER) is the primary mechanism for the removal of many lesions from DNA. This repair process can be broadly divided in two stages: first, incision at damaged sites and second, synthesis of new DNA to replace the oligonucleotide removed by excision. In order to dissect the repair mechanism, we have recently devised a method to analyze the incision reaction in vitro in the absence of repair synthesis (1). Damage-specific incisions take place in a repair reaction in which mammalian cell-free extracts are mixed with undamaged and damaged plasmids. Most of the incision events are accompanied by excision. Using this assay, we investigated here various parameters that specifically affect the level of damage-dependent incision activity by cell-free extracts in vitro. We have defined optimal conditions for the reaction and determined the kinetics of the incision with cell-free extracts from human cells. We present direct evidence that the incision step of NER is ATP-dependent. In addition, we observe that Mn2+ but no other divalent cation can substitute for Mg2+ in the incision reaction.

Repair by human cell extracts of single (6-4) and cyclobutane thymine-thymine photoproducts in DNA

One cis-syn cyclobutane thymine dimer or one (6-4) thymine-thymine photoproduct was built into an identical sequence of a closed-circular M13 duplex DNA, and nucleotide excision repair synthesis carried out by human cell extracts in the area containing each lesion was determined. Extracts from normal cells repaired the (6-4) photoproduct with a patch size of approximately 20-30 nucleotides, but repair was at least 10-fold lower at the cyclobutane dimer. The (6-4) lesion was repaired with comparable efficiency to a single acetylamino-fluorene-guanine adduct in a similar location. Extract from nucleotide excision repair-deficient xeroderma pigmentosum group A cells could not remove any of these adducts but could complete repair of the lesions after incision with Escherichia coli UvrABC proteins. This direct comparison of repair of two UV photoproducts, in an in vitro system where chromatin assembly and transcription are absent, suggests that the more rapid repair of the (6-4) lesion observed in the mammalian cell genome overall is due in part to a significant difference in the ability of the repair complex to locate and incise these lesions in DNA.