Apoptosis ; genetics ; DNA Repair ; DNA-(Apurinic or Apyrimidinic Site) Lyase ; chemistry ; genetics ; physiology ; Humans

The damage to sperm DNA is one of the most important causes of male infertility. Some sperm with damaged DNA may escape from the sperm surveillance mechanism and transmit the damage to the offspring. So research on the damage to sperm DNA has become one of the hot spots in reproductive medicine. The factors that would damage sperm DNA include oxidative stress, microelements, reproductive toxic substances, radioactive rays, and so on, while the body depends on the compressed sperm DNA and anti-oxidation system for the protection of the integrity of sperm DNA. Some drugs such as anti-oxidant, black tea extract, etc, may help to improve and rebuild these protective mechanisms.
Antioxidants ; pharmacology ; DNA Damage ; DNA Repair ; physiology ; Humans ; Male ; Oxidative Stress ; Spermatozoa ; chemistry ; ultrastructure

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*

OBJECTIVEThe assay of DNA mismatch repair (MMR) activity can be used as a biomarker for environmental condition detection and human disease diagnosis. Radioactive ³²P-endlabeled DNA containing mismatch is extensively used as the substrate for MMR activity analyses. The aim of the present study is to develop a simple non-radioactive, but equally specific and sensitive method for the MMR activity assay.

METHODSA fluorescent label was chosen to replace the radioactive isotope label. Sensitive evaluation of the fluorescent label was carried out for the first time, and then the fluorescent label was compared with the isotope label in the MMR activity and DNA binding assays.

RESULTLOD (limit of detection) of the fluorescent label was about 0.1 fmol and the relative signal strength displayed a pretty good linear relationship. Moreover, the fluorescent label method has equivalent sensitivity and performance as compared with the classical radioactive method in experiments.

CONCLUSIONIn light of the sensitivity, reproducibility, safety, rapidity and long lifespan of the fluorescent label, this improved method can be applied to evaluation of biologic and toxic effects of environmental pollutants on man and other forms of life.

Mammalian cells are frequently at risk of DNA damage from both endogenous and exogenous sources. Accordingly, cells have evolved the DNA damage response (DDR) pathways to monitor and assure the integrity of their genome. In cells, the intact and effective DDR is essential for the maintenance of genomic stability and it acts as a critical barrier to suppress the development of cancer in humans. Two central kinases for the DDR pathway are ATM and ATR, which can phosphorylate and activate many downstream proteins for cell cycle arrest, DNA repair, or apoptosis if the damages are irreparable. In the last several years, we and others have made significant progress to this field by identifying BRIT1 (also known as MCPH1) as a novel key regulator in the DDR pathway. BRIT1 protein contains 3 breast cancer carboxyl terminal (BRCT) domains which are conserved in BRCA1, MDC1, 53BP1, and other important molecules involved in DNA damage signaling, DNA repair, and tumor suppression. Our in vitro studies revealed BRIT1 to be a chromatin-binding protein required for recruitment of many important DDR proteins (ATM, MDC1, NBS1, RAD51, BRCA2) to the DNA damage sites. We recently also generated the BRIT1 knockout mice and demonstrated its essential roles in homologous recombination DNA repair and in maintaining genomic stability in vivo. In humans, BRIT1 is located on chromosome 8p23.1, where loss of hetero-zigosity is very common in many types of cancer. In this review, we will summarize the novel roles of BRIT1 in DDR, describe the relationship of BRIT1 deficiency with cancer development, and also discuss the use of synthetic lethality approach to target cancers with HR defects due to BRIT1 deficiency.
Animals ; Chromosomal Proteins, Non-Histone/genetics/metabolism/*physiology ; DNA Damage/genetics/*physiology ; DNA Repair/genetics/*physiology ; Humans ; Mice ; Models, Biological ; Neoplasms/*genetics ; Nerve Tissue Proteins/genetics/metabolism/*physiology

Mammalian cells are frequently at risk of DNA damage from both endogenous and exogenous sources. Accordingly, cells have evolved the DNA damage response (DDR) pathways to monitor and assure the integrity of their genome. In cells, the intact and effective DDR is essential for the maintenance of genomic stability and it acts as a critical barrier to suppress the development of cancer in humans. Two central kinases for the DDR pathway are ATM and ATR, which can phosphorylate and activate many downstream proteins for cell cycle arrest, DNA repair, or apoptosis if the damages are irreparable. In the last several years, we and others have made significant progress to this field by identifying BRIT1 (also known as MCPH1) as a novel key regulator in the DDR pathway. BRIT1 protein contains 3 breast cancer carboxyl terminal (BRCT) domains which are conserved in BRCA1, MDC1, 53BP1, and other important molecules involved in DNA damage signaling, DNA repair, and tumor suppression. Our in vitro studies revealed BRIT1 to be a chromatin-binding protein required for recruitment of many important DDR proteins (ATM, MDC1, NBS1, RAD51, BRCA2) to the DNA damage sites. We recently also generated the BRIT1 knockout mice and demonstrated its essential roles in homologous recombination DNA repair and in maintaining genomic stability in vivo. In humans, BRIT1 is located on chromosome 8p23.1, where loss of hetero-zigosity is very common in many types of cancer. In this review, we will summarize the novel roles of BRIT1 in DDR, describe the relationship of BRIT1 deficiency with cancer development, and also discuss the use of synthetic lethality approach to target cancers with HR defects due to BRIT1 deficiency.
Animals ; Chromosomal Proteins, Non-Histone/genetics/metabolism/*physiology ; DNA Damage/genetics/*physiology ; DNA Repair/genetics/*physiology ; Humans ; Mice ; Models, Biological ; Neoplasms/*genetics ; Nerve Tissue Proteins/genetics/metabolism/*physiology

A common DNA polymerase can replicate DNA which functions normally. However, if DNA suffers damage, the genome can not be replicated by a common DNA polymerase because DNA lesions will block the replication apparatus. Another kind of DNA polymerases in organism, Y-family DNA polymerases which is also called translesion synthesis (TLS) polymerases, can deal with this problem. Their main functions are bypassing the lesions in DNA, replicating the genome and saving the dying cells. This thesis presents a historical review of the literature pertinent to the structure, functions and roles of Y-family DNA polymerases.
DNA Damage ; DNA Repair ; DNA Replication ; DNA-Directed DNA Polymerase ; classification ; metabolism ; physiology ; Humans ; Mutagenesis ; Mutagens ; Proliferating Cell Nuclear Antigen ; genetics

The p53 tumor suppressor has long been envisaged to preserve genetic stability by the induction of cell cycle checkpoints and apoptosis. More recently, p53 has been implicated to play roles in DNA repair responses to genotoxic stresses. UV-damage and the damage caused by certain chemotherapeutics including cisplatin and nitrogen mustards are known to be repaired by the nucleotide excision repair (NER) pathway which is reportedly regulated by p53 and its downstream genes. There are evidences to suggest that the base excision repair (BER) induced by the base-damaging agent methyl methanesulfonate (MMS) is partially deficient in cells lacking functional p53. This result suggests that the activity of BER might be also dependent on the p53 status. In this review, we discuss the possibilities that p53 regulates BER as well as NER; these are one of the most significant potentials of p53 tumor suppressor for repairing the vast majority of DNA damages that is incurred from various environmental stresses.
Animals ; Antineoplastic Agents/pharmacology ; DNA/drug effects ; *DNA Damage ; DNA Repair/*physiology ; Humans ; Mice ; Protein p53/*physiology ; Research Support, Non-U.S. Gov't

DNA double-stranded break (DSB) is one of the most catastrophic damages of genotoxic insult. Inappropriate repair of DNA DSBs results in the loss of genetic information, mutation, and the generation of harmful genomic rearrangements, which predisposes an organism to immunodeficiency, neurological damage, and cancer. The tumor repressor p53 plays a key role in DNA damage response, and has been found to be mutated in 50% of human cancer. p53, p63, and p73 are three members of the p53 gene family. Recent discoveries have shown that human p53 gene encodes at least 12 isoforms. Different p53 members and isoforms play various roles in orchestrating DNA damage response to maintain genomic integrity. This review briefly explores the functions of p53 and its isoforms in DNA DSB repair.
Animals ; DNA Breaks, Double-Stranded ; DNA Repair ; Humans ; Mice ; Protein Isoforms ; physiology ; Tumor Protein p73 ; physiology ; Tumor Suppressor Protein p53 ; genetics ; physiology