A role for the base excision repair enzyme NEIL3 in replication-dependent repair of interstrand DNA cross-links derived from psoralen and abasic sites

Yang, Zhiyu; Nejad, Maryam Imani; Varela, Jacqueline Gamboa; Price, Nathan E.; Wang, Yinsheng; Gates, Kent S.

doi:10.1016/j.dnarep.2017.02.011

Cited by 37 publications

(36 citation statements)

References 175 publications

(220 reference statements)

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“…We note again that extant life unfailingly meets its specificity requirements by managing essentially every chemical transformation it requires using macromolecular machines–machines functioning either as highly selective and specific catalysts (critically, allosterically controllable ones), or as disequilibrium converting nano‐engines (see below), or as dynamic structural elements. In addition it must invest heavily in sophisticated repair and waste disposal, including of course, that of spent electrons . Nothing is left to the indiscriminate and unselective fortunes of mass action solution chemistry.…”

Section: Energy Warm Ponds Hot Soups: Which Idea Animates Essentialmentioning

confidence: 99%

Frankenstein or a Submarine Alkaline Vent: Who Is Responsible for Abiogenesis?

Branscomb

Russell

2018

BioEssays

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Origin of life models based on "energized assemblages of building blocks" are untenable in principle. This is fundamentally a consequence of the fact that any living system is in a physical state that is extremely far from equilibrium, a condition it must itself build and sustain. This in turn requires that it carries out all of its molecular transformations-obligatorily those that convert, and thereby create, disequilibria-using case-specific mechanochemical macromolecular machines. Mass-action solution chemistry is quite unable to do this. We argue in Part 2 of this series that this inherent dependence of life on disequilibria-converting macromolecular machines is also an obligatory requirement for life at its emergence. Therefore, life must have been launched by the operation of abiotic macromolecular machines driven by abiotic, but specifically "life-like", disequilibria, coopted from mineral precipitates that are chemically and physically active. Models grounded in "chemistry-in-a-bag" ideas, however energized, should not be considered.

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Section: Energy Warm Ponds Hot Soups: Which Idea Animates Essentialmentioning

confidence: 99%

Frankenstein or a Submarine Alkaline Vent: Who Is Responsible for Abiogenesis?

Branscomb

Russell

2018

BioEssays

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“…Psoralen-induced monoadducts function as substrates for NEIL1 where HeLa cells deficient in NEIL1 and/or APE1 exhibit hypersensitivity to psoralen upon UVA photoactivation [130]. Furthermore, NEIL1 and NEIL3 have been shown to be involved in the repair of bulky psoralen-induced interstrand cross-links [131][132][133]. On the other hand, cisplatin cytotoxicity is attributed to inducing different types of DNA lesions including monoadducts, intrastrand and interstrand cross-links [134] in addition to resulting in an increased generation of ROS and oxidative DNA damage [28].…”

Section: Sensitizing Cells To Cancer Therapy-induced Dna Damagementioning

confidence: 99%

Targeting BER enzymes in cancer therapy

et al. 2018

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Base excision repair (BER) repairs mutagenic or genotoxic DNA base lesions, thought to be important for both the etiology and treatment of cancer. Cancer phenotypic stress induces oxidative lesions, and deamination products are responsible for one of the most prevalent mutational signatures in cancer. Chemotherapeutic agents induce genotoxic DNA base damage that are substrates for BER, while synthetic lethal approaches targeting BER-related factors are making their way into the clinic. Thus, there are three strategies by which BER is envisioned to be relevant in cancer chemotherapy: (i) to maintain cellular growth in the presence of endogenous DNA damage in stressed cancer cells, (ii) to maintain viability after exogenous DNA damage is introduced by therapeutic intervention, or (iii) to confer synthetic lethality in cancer cells that have lost one or more additional DNA repair pathways. Here, we discuss the potential treatment strategies, and briefly summarize the progress that has been made in developing inhibitors to core BER-proteins and related factors.

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“…The DNA‐damaging effects of radiation, and possibly gas plasma sterilization, can be counteracted by repair pathways such as homologous and nonhomologous recombination, base excision repair, and mismatch repair (Natarajan, ; Shintani, Sakudo, Burke, & McDonnell, ). These mechanisms use various enzymes such as polymerases, helicases, ligases, endonucleases, and glycosylases to identify and repair DNA‐lesions which would normally be lethal to the cell (Natarajan, ; Yang et al., ). The unregulated growth of cancer cells can cause lethal mutations or repress the expression of some DNA repair enzymes (Kelley et al., ).…”

Section: Antibacterial Biomoleculesmentioning

confidence: 99%

Integration of Emerging Biomedical Technologies in Meat Processing to Improve Meat Safety and Quality

Ravensdale

Coorey

Dykes

2018

Comp Rev Food Sci Food Safe

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Modern-day processing of meat products involves a series of complex procedures designed to ensure the quality and safety of the meat for consumers. As the size of abattoirs increases, the logistical problems associated with large-capacity animal processing can affect the sanitation of the facility and the meat products, potentially increasing transmission of infectious diseases. Additionally, spoilage of food from improper processing and storage increases the global economic and ecological burden of meat production. Advances in biomedical and materials science have allowed for the development of innovative new antibacterial technologies that have broad applications in the medical industry. Additionally, new approaches in tissue engineering and nondestructive cooling of biological specimens could significantly improve organ transplantation and tissue grafting. These same strategies may be even more effective in the preservation and protection of meat as animal carcasses are easier to manipulate and do not have the same stringent requirements of care as living patients. This review presents potential applications of emerging biomedical technologies in the food industry to improve meat safety and quality. Future research directions investigating these new technologies and their usefulness in the meat processing chain along with regulatory, logistical, and consumer perception issues will also be discussed.

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A role for the base excision repair enzyme NEIL3 in replication-dependent repair of interstrand DNA cross-links derived from psoralen and abasic sites

Cited by 37 publications

References 175 publications

Frankenstein or a Submarine Alkaline Vent: Who Is Responsible for Abiogenesis?

Frankenstein or a Submarine Alkaline Vent: Who Is Responsible for Abiogenesis?

Targeting BER enzymes in cancer therapy

Integration of Emerging Biomedical Technologies in Meat Processing to Improve Meat Safety and Quality

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