Animals ; Mice ; DNA Repair ; DNA Breaks, Double-Stranded ; DNA/metabolism* ; DNA Damage

Meiosis is an essential step in gametogenesis which is the key process in sexually reproducing organisms as meiotic aberrations may result in infertility. In meiosis, programmed DNA double-strand break (DSB) formation is one of the fundamental processes that are essential for maintaining homolog interactions and correcting segregation of chromosomes. Although the number and distribution of meiotic DSBs are tightly regulated, still abnormalities in DSB formation are known to cause meiotic arrest and infertility. This review is a detailed account of molecular bases of meiotic DSB formation, its evolutionary conservation, and variations in different species. We further reviewed the mutations of DSB formation genes in association with human infertility and also proposed the future directions and strategies about the study of meiotic DSB formation.
DNA Breaks, Double-Stranded ; DNA Repair/genetics* ; Humans ; Infertility/genetics* ; Meiosis/physiology*

Programmed DNA double-strand breaks (DSBs) are necessary for meiosis in mammals. A sufficient number of DSBs ensure the normal pairing/synapsis of homologous chromosomes. Abnormal DSB repair undermines meiosis, leading to sterility in mammals. The DSBs that initiate recombination are repaired as crossovers and noncrossovers, and crossovers are required for correct chromosome separation. Thus, the placement, timing, and frequency of crossover formation must be tightly controlled. Importantly, mutations in many genes related to the formation and repair of DSB result in infertility in humans. These mutations cause nonobstructive azoospermia in men, premature ovarian insufficiency and ovarian dysgenesis in women. Here, we have illustrated the formation and repair of DSB in mammals, summarized major factors influencing the formation of DSB and the theories of crossover regulation.
Animals ; Chromosome Segregation ; DNA Breaks, Double-Stranded ; DNA Repair/physiology* ; Humans ; Mammals/genetics*

The CRISPR system is able to accomplish precise base editing in genomic DNA, but relies on the cellular homology-directed recombination repair pathway and is therefore extremely inefficient. Base editing is a new genome editing technique developed based on the CRISPR/Cas9 system. Two base editors (cytosine base editor and adenine base editor) were developed by fusing catalytically disabled nucleases with different necleobase deaminases. These two base editors are able to perform C>T (G>A) or A>G (T>C) transition without generating DNA double-stranded breaks. The base editing technique has been widely used in gene therapy, animal models construction, precision animal breeding and gene function analysis, providing a powerful tool for basic and applied research. This review summarized the development process, technical advantages, current applications, challenges and perspectives for base editing technique, aiming to help the readers better understand and use the base editing technique.
Adenine ; Animals ; CRISPR-Cas Systems/genetics* ; Cytosine ; DNA Breaks, Double-Stranded ; Gene Editing

Traditional pig breeding has a long cycle and high cost, and there is an urgent need to use new technologies to revitalize the pig breeding industry. The recently emerged CRISPR/Cas9 genome editing technique shows great potential in pig genetic improvement, and has since become a research hotspot. Base editor is a new base editing technology developed based on the CRISPR/Cas9 system, which can achieve targeted mutation of a single base. CRISPR/Cas9 technology is easy to operate and simple to design, but it can lead to DNA double strand breaks, unstable gene structures, and random insertion and deletion of genes, which greatly restricts the application of this technique. Different from CRISPR/Cas9 technique, the single base editing technique does not produce double strand breaks. Therefore, it has higher accuracy and safety for genome editing, and is expected to advance the pig genetic breeding applications. This review summarized the working principle and shortcomings of CRISPR/Cas9 technique, the development and advantages of single base editing, the principles and application characteristics of different base editors and their applications in pig genetic improvement, with the aim to facilitate genome editing-assisted genetic breeding of pig.
Animals ; Swine/genetics* ; Gene Editing ; CRISPR-Cas Systems/genetics* ; DNA Breaks, Double-Stranded

Animals ; Antigens, Nuclear ; DNA ; genetics ; metabolism ; DNA Breaks, Double-Stranded ; DNA Repair ; DNA-Binding Proteins ; Humans ; Ku Autoantigen

This study was aimed to explore the pathogenesis of type III familial hemophagocytic lymphohistiocytosis (FHL3) via susceptibility gene UNC13D involving in homologous recombination repair (HRR) of DNA double-strand break (DSB). By means of DNA homologous recombination repair, the change of homologous recombination repair rate of normal control cells and DR-U2OS cells after down-regulation of UNC13D was detected; the UNC13D gene related function was explored. The results showed that DR-U2OS cells displayed a significant reduction in homologous recombination repair of DNA DSB after siRNA knockdown of UNC13D, compared to its normal control cell counterparts (P < 0.05), suggesting that UNC13D was involved in DNA double-stranded breakage repair. It is concluded that UNC13D gene mutation may be involved in the pathogenesis of FHL3 via its dual effects of both the cytotoxic granule exocytosis and decrease of homologous recombination repair rate after the DNA double-strand break, therefore, providing a new theoretical basis to reveal the pathogenesis of FHL3.
DNA Breaks, Double-Stranded ; DNA-Binding Proteins ; genetics ; Humans ; Lymphohistiocytosis, Hemophagocytic ; classification ; genetics ; Membrane Proteins ; genetics ; Recombinational DNA Repair

OBJECTIVETo construct a system of I-SceI and induce a site-specific DNA double-strand break (DSB) in the genome of HepG2 for using this system in future exploration of the potential mechanisms of HBV integration by DSB repair.

METHODSThe eukaryotic expression plasmid pEGFP2 was constructed and transfected into human hepatoma cell line HepG2. The positive neomycin-resistant transfected cell clones were generated by G418 selection. Then the positive cells containing an 18-bp I-SceI endonuclease site were transfected transiently with pCMV(3NLS) I-SceI, an I-SceI expression plasmid. At 24 h post-transfection with pCMV (3NLS) I-SceI, gamma-H2AX, as an early cellular marker of DSB, was detected using immunocytochemistry and Western blot analysis.

RESULTSRestriction analysis and DNA sequencing verified that the plasmid pEGFP2 was successfully constructed. gamma-H2AX increased significantly in cells transfected with the I-SceI system.

CONCLUSIONSGenomic DSB can be induced into HepG2 by introducing an I-SceI system. The cell model could provide us with a practical tool for further study to see if DSB is a potential target for HBV integration.

Carcinoma, Hepatocellular ; genetics ; DNA Breaks, Double-Stranded ; DNA Repair ; Flap Endonucleases ; genetics ; Hep G2 Cells ; Humans ; Liver Neoplasms ; genetics ; Plasmids

Although some mutations are beneficial and are the driving force behind evolution, it is important to maintain DNA integrity and stability because it contains genetic information. However, in the oxygen-rich environment we live in, the DNA molecule is under constant threat from endogenous or exogenous insults. DNA damage could trigger the DNA damage response (DDR), which involves DNA repair, the regulation of cell cycle checkpoints, and the induction of programmed cell death or senescence. Dysregulation of these physiological responses to DNA damage causes developmental defects, neurological defects, premature aging, infertility, immune system defects, and tumors in humans. Some human syndromes are characterized by unique neurological phenotypes including microcephaly, mental retardation, ataxia, neurodegeneration, and neuropathy, suggesting a direct link between genomic instability resulting from defective DDR and neuropathology. In this review, rare human genetic disorders related to abnormal DDR and damage repair with neural defects will be discussed.
Aging ; Aging, Premature ; Ataxia ; Cell Cycle Checkpoints ; Cell Death ; Central Nervous System Diseases ; DNA Breaks, Double-Stranded ; DNA Breaks, Single-Stranded ; DNA Damage* ; DNA Repair ; DNA* ; Genomic Instability ; Humans* ; Immune System ; Infertility ; Intellectual Disability ; Microcephaly ; Neuropathology ; Phenotype

OBJECTIVETo study DNA double-strand breaks of human peripheral lymphocytes exposed to lead with flow cytometry (FCM).

METHODSThe lymphocytes were obtained from 36 workers occupationally exposed to lead and 70 residents without occupational exposure to lead. DNA double-strand breaks were detected by flow cytometer assay. The lymphocytes from health people were incubated with lead at different doses and time, FCM assay was used to detect DNA double-strand breaks.

RESULTSDNA double-strand breaks and fluorescence intensity of high exposed group and low exposed group were 41.76% ± 28.57%, 9.90 ± 3.35 and 33.18% ± 30.64%, 9.39 ± 4.83, respectively, which were significantly higher than those (0.28% ± 0.28% and 6.95 ± 2.93) of control group (P<0.05). The results of in vitro experiment indicated that DNA double-strand breaks of lymphocytes exposed to Pb at the dose of 125.0, 250.0, 500.0 µmol/L for 1 and 2 h were significantly different from those of the negative control group and positive control group (P<0.01). DNA double-strand breaks increased at beginning and then decreased with lead doses.

CONCLUSIONLead can induce DNA double-strand breaks, γH2AX detected using flow cytometer assay can be used to measure the DSBs of DNA in large samples.

Adult ; Cells, Cultured ; DNA Breaks, Double-Stranded ; Female ; Humans ; In Vitro Techniques ; Lead ; toxicity ; Lymphocytes ; drug effects ; pathology ; Male ; Occupational Exposure