Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts:   Target Concepts:
Query: EC:3.1.30.2 (endonuclease)
 18,621 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The multifunctional mammalian apurinic/apyrimidinic endonuclease (APE) is responsible for the repair of apurinic/apyrimidinic sites in DNA. In addition, this enzyme has been shown to function as a redox factor facilitating the DNA-binding capability of JUN and FOS, as well as numerous other transcription factors through the alteration of the transcription factor redox state. Biochemical studies of organ homogenates have shown that APE is present in the different tissues studied at similar concentrations. The present study examines the immunohistochemical distribution of APE in several organs and demonstrates new and unexpected patterns of cellular and subcellular localization of this enzyme. In the hippocampus, the APE protein was highly expressed in neurons of the dentate gyrus and regions CA3 and CA4, and unexpectedly, the staining was primarily cytoplasmic. AP endonuclease immunoreactivity in the cerebellum was found in the granule and Purkinje cells, both cytoplasmic and nuclear. APE staining of the hypoglossal nucleus of the brainstem, where motor neurons that control tongue movement reside, showed reactivity in the cytoplasmic Nissl substance. Skin, liver, and duodenum demonstrated nuclear staining; however, in the duodenum, only the enterocyte nuclei of the proximal villus and the crypts of Lieberkuhn were stained, with no staining of the distal villus. These results suggest that APE has different regulatory and functional roles in different cells and organs of the body. This study shows the importance of correlating in vitro findings in tissue culture cells with the organism as a whole. The cytoplasmic staining seen in parts of the brain and in liver suggests that there may be additional functions for the APE yet to be described.
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PMID:Differential cellular and subcellular expression of the human multifunctional apurinic/apyrimidinic endonuclease (APE/ref-1) DNA repair enzyme. 852 99

The multifunctional mammalian apurinic/apyrimidinic (AP) endonuclease (APE) is responsible for the repair of AP sites in DNA. In addition, this enzyme has been shown to function as a redox factor facilitating the DNA-binding capability of JUN and FOS, HeLa AP-1, and numerous other transcription factors, including Myb, members of the CREB family and nuclear factor-kappa B. Although previously presumed to be ubiquitously expressed at comparable levels in all tissues and cell types, recent evidence has shown APE to vary significantly in its expression between tissues and even within tissues. To further characterize APE expression at various stages of cervical neoplasia, we investigated the levels of APE protein expression using immunohistochemistry in normal cervix, pre-invasive and invasive squamous lesions of the cervix, as well as in cervical cancer cell lines. We report here that the APE protein is predominantly expressed in the nuclei of cells from both primary tumors and cervical cell lines, but the level of APE protein is significantly and dramatically elevated in cervical cancer tissue. These results implicate the use of anti-APE antibodies as an effective reagent in the early detection of premalignant and malignant cancer of the cervix. These findings are suggestive that the increase of a DNA repair enzyme in cancerous cells may allow these cells to be refractive to chemotherapy.
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PMID:The apurinic/apyrimidinic endonuclease (APE/ref-1) DNA repair enzyme is elevated in premalignant and malignant cervical cancer. 942 67

A rational selection of probiotic microorganisms is an important challenge and requires the definition of fundamental information about the physiology and genetics of candidate strains. In this study, selected Lactobacillus (Lact.) strains already characterized in a previous study for their capability to resist low pH and to grow in conditions simulating the intestinal environment, were further investigated to explore their probiotic properties, such as the adhesion capability to intestinal human Caco-2 cell lines and their growth behaviour in the presence of various prebiotic carbohydrates. At first 25 Lactobacillus strains were characterized by pulsed field gel electrophoresis using the endonuclease NotI. Among them, 13 strains belonging to the Lact. plantarum-group were identified at species level by a multiplex PCR assay. Subsequently 11 Lactobacillus strains showing different PFGE restriction pattern and the best acid- and bile-resistances, were chosen to investigate their in vitro adhesion capability to human intestinal epithelial cells and their fermentation properties of five prebiotic substances (FOS, Inulin, IMO, GOS and lactulose) at a concentration of 2%. The 11 strains analysed in this study possessed good adhesion capability to Caco-2 cell layers and, in particular, the eight strains belonging to the Lact. plantarum-group showed the higher final number of viable adhering cells. Moreover a species-related fermentative behaviour was pointed out and the strain Lact. paracasei EL7 was the only one able to grow in the presence of all prebiotics tested. In conclusion the strains of Lactobacillus studied in this research could be further investigated to assess possible in vivo human health benefits.
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PMID:Potential probiotic Lactobacillus strains from fermented sausages: Further investigations on their probiotic properties. 2206 58

The exposure to ultraviolet radiation (UVR) is one of the most important risk factors for skin aging and increases the risk of malignant transformation. Telomere shortening and an altered expression of the proto-oncogene c-FOS are among the key molecular mechanisms associated with photoaging and tumorigenesis. Photolyase from A. nidulans and endonuclease from M. luteus are xenogenic DNA repair enzymes which can reverse the molecular events associated with skin aging and carcinogenosis caused by UVR exposure. Therefore, the purpose of this study was to investigate whether the topical application of preparations containing DNA repair enzymes may prevent UVR-induced acute telomere shortening and FOS gene hyperexpression in human skin biopsies. Twelve volunteers (Fitzpatrick skin types I and II) were enrolled for this experimental study, and six circular areas (10 mm diameter) were marked out on the nonexposed lower back of each participant. One site was left untreated (site 1: negative control), whereas the remaining five sites (designated sites 2-6) were exposed to solar-simulated UVR at 3 times the MED on four consecutive days. Site 2 received UVR only (site 2: positive control), whereas the following products were applied to sites 3-6, respectively: vehicle (moisturizer base cream; applied both 30 minutes before and immediately after each irradiation; site 3); a traditional sunscreen (SS, SPF 50) 30 minutes before irradiation and a vehicle immediately after irradiation (site 4); a SS 30 minutes before irradiation and an endonuclease preparation immediately after irradiation (site 5); a SS plus photolyase 30 minutes before irradiation and an endonuclease preparation immediately after irradiation (site 6). Skin biopsies were taken 24 h after the last irradiation. The degree of telomere shortening and c-FOS gene expression were measured in all specimens. Strikingly, the combined use of a SS plus photolyase 30 minutes before irradiation and an endonuclease preparation immediately after irradiation completely abrogated telomere shortening and c-FOS gene hyperexpression induced by the experimental irradiations. We conclude that the topical application of preparations containing both photolyase from A. nidulans and endonuclease from M. luteus may be clinically useful to prevent skin aging and carcinogenesis by abrogating UVR-induced telomere shortening and c-FOS gene hyperexpression.
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PMID:Topical application of preparations containing DNA repair enzymes prevents ultraviolet-induced telomere shortening and c-FOS proto-oncogene hyperexpression in human skin: an experimental pilot study. 2400 49