Diverse functions of DNA glycosylases processing oxidative base lesions in brain

PARP1 inhibitor niraparib exerts synergistic antimyeloma effect with bortezomib through inducing DNA damage and inhibiting DNA repair

Despite the improvements in outcomes for patients with multiple myeloma (MM) over the past decade, the disease remains incurable, and even those patients who initially respond favorably to induction therapy eventually suffer from relapse. Consequently, there is an urgent need for the development of novel therapeutic agents and strategies to enhance the treatment outcomes for patients with MM. The proteasome inhibitor bortezomib (BTZ) elicits endoplasmic reticulum (ER) stress and oxidative stress in MM cells, subsequent DNA damage, ultimately inducing cell apoptosis. Poly (ADP-ribose) polymerase 1 (PARP1) acts as a pivotal enzyme for DNA repair and thus deficient PARP1 renders cells more susceptible to DNA-damaging agents. Conceivably, targeting PARP1 may enhance BTZ-induced DNA damage and cell death in MM cells. In this study, Colony formation, CCK-8, and EdU-labeling assays were conducted to evaluate the effects on MM cell proliferation. The ZIP score was used to assess synergy. Apoptosis and intercellular ROS levels were analyzed using flow cytometry and fluorescence microscopy, respectively. Immunofluorescence and Western blot analyses were used to assess protein expression. The correlation between PARP1 expression levels and the clinical prognosis was examined by tumor-related databases and bioinformatics. The results show that PARP1 is overexpressed in patient MM cells and is associated with a poor prognosis. PARP1 inhibitor niraparib decreases MM cell growth and arrests cell cycle progression at the G2/M phase. When combined with BTZ, it synergistically increases DNA damage, inhibits proliferation, and induces apoptosis. Mechanistically, Niraparib facilitates BTZ-induced ROS elevation, causing DNA double-strand breaks (DSBs), and simultaneously inhibits lesion repair by impeding the expression of repair proteins XRCC1 (X-ray repair cross-complementing protein 1)and POLβ (DNA polymerase beta). Overall, Niraparib plus bortezomib represent a promising approach for treatment of MM.

Proteins Associated with Neurodegenerative Diseases: Link to DNA Repair

The nervous system is susceptible to DNA damage and DNA repair defects, and if DNA damage is not repaired, neuronal cells can die, causing neurodegenerative diseases in humans. The overall picture of what is known about DNA repair mechanisms in the nervous system is still unclear. The current challenge is to use the accumulated knowledge of basic science on DNA repair to improve the treatment of neurodegenerative disorders. In this review, we summarize the current understanding of the function of DNA damage repair, in particular, the base excision repair and double-strand break repair pathways as being the most important in nervous system cells. We summarize recent data on the proteins involved in DNA repair associated with neurodegenerative diseases, with particular emphasis on PARP1 and ND-associated proteins, which are involved in DNA repair and have the ability to undergo liquid-liquid phase separation.

Age- and sex-dependent effects of DNA glycosylase Neil3 on amyloid pathology, adult neurogenesis, and memory in a mouse model of Alzheimer's disease

Oxidative stress generating DNA damage has been shown to be a key characteristic in Alzheimer's disease (AD). However, how it affects the pathogenesis of AD is not yet fully understood. Neil3 is a DNA glycosylase initiating repair of oxidative DNA base lesions and with a distinct expression pattern in proliferating cells. In brain, its function has been linked to hippocampal-dependent memory and to induction of neurogenesis after stroke and in prion disease. Here, we generated a novel AD mouse model deficient for Neil3 to study the impact of impaired oxidative base lesion repair on the pathogenesis of AD. Our results demonstrate an age-dependent decrease in amyloid-β (Aβ) plaque deposition in female Neil3-deficient AD mice, whereas no significant difference was observed in male mice. Furthermore, male but not female Neil3-deficient AD mice show reduced neural stem cell proliferation in the adult hippocampus and impaired working memory compared to controls. These effects seem to be independent of DNA repair as both sexes show increased level of oxidative base lesions in the hippocampus upon loss of Neil3. Thus, our findings suggest an age- and sex-dependent role of Neil3 in the progression of AD by altering cerebral Aβ accumulation and promoting adult hippocampal neurogenesis to maintain cognitive function.

MUTYH Actively Contributes to Microglial Activation and Impaired Neurogenesis in the Pathogenesis of Alzheimer's Disease

Oxidative stress is a major risk factor for Alzheimer's disease (AD), which is characterized by brain atrophy, amyloid plaques, neurofibrillary tangles, and loss of neurons. 8-Oxoguanine, a major oxidatively generated nucleobase highly accumulated in the AD brain, is known to cause neurodegeneration. In mammalian cells, several enzymes play essential roles in minimizing the 8-oxoguanine accumulation in DNA. MUTYH with adenine DNA glycosylase activity excises adenine inserted opposite 8-oxoguanine in DNA. MUTYH is reported to actively contribute to the neurodegenerative process in Parkinson and Huntington diseases and some mouse models of neurodegenerative diseases by accelerating neuronal dysfunction and microgliosis under oxidative conditions; however, whether or not MUTYH is involved in AD pathogenesis remains unclear. In the present study, we examined the contribution of MUTYH to the AD pathogenesis. Using postmortem human brains, we showed that various types of MUTYH transcripts and proteins are expressed in most hippocampal neurons and glia in both non-AD and AD brains. We further introduced MUTYH deficiency into App ^{NL-G-F/NL-G-F} knock-in AD model mice, which produce humanized toxic amyloid-β without the overexpression of APP protein, and investigated the effects of MUTYH deficiency on the behavior, pathology, gene expression, and neurogenesis. MUTYH deficiency improved memory impairment in App ^{NL-G-F/NL-G-F} mice, accompanied by reduced microgliosis. Gene expression profiling strongly suggested that MUTYH is involved in the microglial response pathways under AD pathology and contributes to the phagocytic activity of disease-associated microglia. We also found that MUTYH deficiency ameliorates impaired neurogenesis in the hippocampus, thus improving memory impairment. In conclusion, we propose that MUTYH, which is expressed in the hippocampus of AD patients as well as non-AD subjects, actively contributes to memory impairment by inducing microgliosis with poor neurogenesis in the preclinical AD phase and that MUTYH is a novel therapeutic target for AD, as its deficiency is highly beneficial for ameliorating AD pathogenesis.

DNA repair enzyme NEIL3 enables a stable neural representation of space by shaping transcription in hippocampal neurons

DNA repair enzymes are essential for the maintenance of the neuronal genome and thereby proper brain functions. Emerging evidence links DNA repair to epigenetic gene regulation; however, its contribution to different transcriptional programs required for neuronal functions remains elusive. In this study, we identified a role of the DNA repair enzyme NEIL3 in modulating the maturation and function of hippocampal CA1 neurons by shaping the CA1 transcriptome during postnatal development and in association with spatial behavior. We observed a delayed maturation in Neil3^-/- CA1 and identified differentially regulated genes required for hippocampal development. We revealed impaired spatial stability in Neil3^-/- CA1 place cells and found spatial experience-induced gene expression essential for synaptic plasticity. This is the first study that links molecular underpinnings of DNA repair to the neural basis of spatial cognition beyond animals' behavioral phenotypes, thus shedding light on the molecular determinants enabling a stable neural representation of space.

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NEIL3 impacts CA1 maturation by shaping transcription during development

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NEIL3 depletion leads to impaired function of CA1 place cells

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NEIL3 shapes transcription in hippocampal CA1 during behavior

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NEIL3 impacts experience-induced expression of immediate early genes (IEGs).

Mitochondrial abnormalities: a hub in metabolic syndrome-related cardiac dysfunction caused by oxidative stress

Metabolic syndrome (MetS) refers to a group of cardiovascular risk elements comprising insulin resistance, obesity, dyslipidemia, increased glucose intolerance, and increased blood pressure. Individually, all the MetS components can lead to cardiac dysfunction, while their combination generates additional risks of morbidity and mortality. Growing evidence suggests that oxidative stress, a dominant event in cellular damage and impairment, plays an indispensable role in cardiac dysfunction in MetS. Oxidative stress can not only disrupt mitochondrial activity through inducing oxidative damage to mitochondrial DNA, RNA, lipids, and proteins but can also impair cardiomyocyte contractile function via mitochondria-related oxidative modifications of proteins central to excitation-contraction coupling. Furthermore, excessive reactive oxygen species (ROS) generation can lead to the activation of several mitochondria apoptotic signaling pathways, release of cytochrome c, and eventual induction of myocardial apoptosis. This review will focus on such processes of mitochondrial abnormalities in oxidative stress induced cardiac dysfunction in MetS.

Genomic Uracil and Aberrant Profile of Demethylation Intermediates in Epigenetics and Hematologic Malignancies

DNA of all living cells undergoes continuous structural and chemical alterations resulting from fundamental cellular metabolic processes and reactivity of normal cellular metabolites and constituents. Examples include enzymatically oxidized bases, aberrantly methylated bases, and deaminated bases, the latter largely uracil from deaminated cytosine. In addition, the non-canonical DNA base uracil may result from misincorporated dUMP. Furthermore, uracil generated by deamination of cytosine in DNA is not always damage as it is also an intermediate in normal somatic hypermutation (SHM) and class shift recombination (CSR) at the Ig locus of B-cells in adaptive immunity. Many of the modifications alter base-pairing properties and may thus cause replicative and transcriptional mutagenesis. The best known and most studied epigenetic mark in DNA is 5-methylcytosine (5mC), generated by a methyltransferase that uses SAM as methyl donor, usually in CpG contexts. Oxidation products of 5mC are now thought to be intermediates in active demethylation as well as epigenetic marks in their own rights. The aim of this review is to describe the endogenous processes that surround the generation and removal of the most common types of DNA nucleobase modifications, namely, uracil and certain epigenetic modifications, together with their role in the development of hematological malignances. We also discuss what dictates whether the presence of an altered nucleobase is defined as damage or a natural modification.

DNA glycosylase Neil2 contributes to genomic responses in the spleen during clinical prion disease

The DNA glycosylase Neil2 is a member of the base excision repair (BER) family of enzymes, which are important for repair of oxidative DNA damage. Specifically, Neil2 participates in repair of oxidized bases in single-stranded DNA of transcriptionally active genes. Mice with genetic ablation of Neil2 (Neil2^-/-) display no overt phenotypes, but an age-dependent accumulation of oxidative DNA damage and increased inflammatory responsiveness. In young mice intra-cerebrally inoculated with prions, vigorous prion propagation starts rapidly in the germinal follicles of the spleen due to inoculum spillover. Here, we compare experimental prion disease in Neil2^-/- mice with that in wild-type mice at disease onset and end-stage. Specifically, we investigated disease progression, accumulation of DNA damage, and mitochondrial respiratory complex activity in brain and spleen. We used genome-wide RNA sequencing of the spleen to compare the immune responses to prion propagation between the two groups of mice, at both onset and end-stage prion disease. The Neil2^-/- mice deteriorated more rapidly than wild-type mice after onset of clinical signs. Levels of DNA damage in brain increased in both mouse groups, slightly more in the Neil2^-/- mice. Transcriptome data from spleen at disease onset were similar between the mouse groups with moderate genomic responses. However, at end-stage a substantial response was evident in the wild-type mice but not in Neil2^-/- mice. Our data show that Neil2 counteracts toxic signaling in clinical prion disease, and this is separate from gross pathological manifestations and PrP^Sc accumulation.