Nuclear DNA

About: Nuclear DNA is a research topic. Over the lifetime, 3933 publications have been published within this topic receiving 185830 citations.

Human globin gene analysis for a patient with beta-o/delta beta-thalassemia

Abstract: Complementary DNA (cDNA) was prepared with RNA-dependent DNA polymerase from human globin messenger RNA (mRNA). Annealing and translation experimenta with total mRNA from circulating cells from a patient with heterozygous beta/heterozygous beta-delta-o thalassemia (beta-o/delta beta-o-thalassemia) demonstrated no detectable mRNA for beta-globin. cDNA enriched in sequences homologous to beta-globin mRNA was prepared by hydroxylapatite fractionation of hybrids formed between beta-o/delta beta-o-thalassemic mRNA and cDNA made from mRNA from a patient with alpha-thalassemia (hemoglobin H disease). The rate of annealing of this beta-enriched cDNA to normal human nuclear DNA was that of a sequence present as only a single copy per haploid genome. The beta-enriched cDNA annealed to the beta-o-delta beta-o-thalassemia total DNA with approximately the same kinetics as to normal DNA, indicating that no total gene deletion of beta-globin genes from the diploid genome has occurred, although the accuracy of the technique could not exclude with certainty a partial deletion or a deletion of a beta-globin gene from only one of the haploid genomes. This demonstrates that at least one of the beta-o- or the delta beta-o-thalassemia haploid genomes in this case contains a substantially intact beta-globin gene.

NtPolI-like1 and NtPolI-like2, bacterial DNA polymerase I homologs isolated from BY-2 cultured tobacco cells, encode DNA polymerases engaged in DNA replication in both plastids and mitochondria.

Abstract: Two cDNAs encoding homologs of bacterial DNA polymerase I were isolated from cultured tobacco (Nicotiana tabacum) BY-2 cells, and the corresponding genes were named NtPolI-like1 and NtPolI-like2. High sequence similarity suggested that they are orthologous genes each derived from respective parental species of N. tabacum, an allotetraploid plant. Each of the NtPolIlike1/2 gene products had a putative transit peptide for plastid localization at the N-terminus, followed by a 3 0 -5 0 exonuclease domain in the internal region, and a DNA polymerase domain in the C-terminal region. Among family A DNA polymerases, NtPolI-like proteins formed, together with other plant DNA polymerase I homologs, a phylogenetic group distinct from mitochondrial DNA polymerase c in animals and fungi, as well as eukaryotic cell nuclear-localized repair enzymes. In contrast to computer predictions, experiments with green fluorescent protein (GFP) fusion protein and Western blotting analysis suggested dual targeting of the gene products to both plastids and mitochondria. The recombinant NtPolI-like2 protein exhibited DNA polymerase activity in vitro. Their biochemical character roughly coincided with those of the 116 kDa DNA polymerases found in the plastid and mitochondrial nuclei (nucleoids) isolated from BY-2 cells. Pre-treatment of the organelle nuclear extracts with antiNtPolI-like antibody removed most of the DNA polymerase activity. Reverse transcription–PCR (RT–PCR) and Western blotting analyses demonstrated transient activation of NtPolI-like gene expression in the initial phase of cell proliferation, exactly when the 116 kDa DNA polymerases in the isolated organelle nuclei were activated and preferential synthesis of organelle DNAs occurred. Taken together, our results suggest that NtPolI-like1/2 genes encode DNA polymerases engaged in DNA replication in both plastids and mitochondria.

Preferential formation and repair of chromium-induced DNA adducts and DNA-protein crosslinks in nuclear matrix DNA

Abstract: The distributions of chromium-DNA adducts and DNA-protein crosslinks induced by treatment of intact CHO cells with carcinogenic chromium were examined in distinct chromatin subfractions: a chromatin subfraction released by digestion of isolated nuclei with micrococcal nuclease (1SF, 14% of total nuclear DNA), bulk chromatin (74% of total DNA) and a nuclear matrix fraction (12% of total DNA). The identity of the matrix fraction was confirmed by hybridization of DNA from each subfraction with a cDNA probe prepared from total mRNA isolated from CHO cells, which showed that the 1SF and nuclear matrix fractions were 2.3- and 3.8-fold enriched in actively transcribed genes respectively, compared to total unfractionated DNA. Immediately following treatment of cells with 150 microM sodium chromate for 2 h the binding of chromium to each chromatin fraction was found to be non-uniform. Compared with total unfractionated nuclei, the nuclear matrix fractions were enriched in chromatin-bound chromium (3.4-fold), whereas the bulk chromatin fraction was relatively depleted (0.5-fold). Approximately 13% of nuclear chromium was associated with the detergent-soluble lipid component of nuclei. A similar distribution of chromatin-bound chromium was also apparent 24 h after the chromate treatment. Immediately after the 2 h chromate treatment, chromium-DNA adducts were detected in all the chromatin subfractions. Total nuclear and bulk chromatin DNA contained similar levels of this type of damage. The 1SF fraction was depleted approximately 3-fold in this type of damage compared with total nuclear DNA. In contrast, the nuclear matrix was markedly enriched in chromium-DNA adducts (approximately 4-fold compared with total nuclear DNA) at this time. As previously demonstrated, chromium-DNA adducts in total nuclear DNA decreased within the first 24 h, but thereafter persisted at a similar level. Chromium-DNA adducts in nuclear matrix DNA also reached maximum levels at the end of the 2 h treatment and decreased to 68% and 39% of this level by 24 and 48 h after treatment respectively. In contrast, the adduct levels in the 1SF and bulk chromatin fractions did not change up to 48 h after treatment. Chromium-induced DNA-protein crosslinks, which were stable to 8 M urea and 2% SDS, occurred almost exclusively in the nuclear matrix fraction. The crosslinks in this fraction reached a maximum level at the end of the 2 h treatment, but returned to control levels 24 h later.(ABSTRACT TRUNCATED AT 400 WORDS)

Nuclear envelope defects impede a proper response to micronuclear DNA lesions

Abstract: When damage is inflicted in nuclear DNA, cells activate a hierarchical plethora of proteins that constitute the DNA damage response machinery. In contrast to the cell nucleus, the ability of micronuclear DNA lesions to activate this complex network is controversial. In order to determine whether the DNA contained in micronuclei is protected by the cellular damage response system, we studied the recruitment of excision repair factors to photolesions inflicted in the DNA of radiation-induced micronuclei. To perform this analysis, primary human dermal fibroblasts were exposed to UV-C light to induce photolesions in nuclear and micronuclear DNA. By means of immunofluorescence techniques, we observed that most micronuclei were devoid of NER factors. We conclude that UV photoproducts in micronuclei are mostly unable to generate an effective DNA damage response. We observed that the micronuclear envelope structure is a determinant factor that influences the repair of the DNA lesions inside micronuclei. Therefore, our results allow us to conclude that photolesions in radiation-induced micronuclei are poorly processed because the repair factors are unable to reach the micronuclear chromatin when a micronucleus is formed or after a genotoxic insult.