Both chloroplastic and cytosolic phosphoglycerate kinase isozymes are present in the pea leaf nucleus

Summary. Phosphoglycerate kinase (EC 2.7.2.3) occurs in chloroplasts, cytosol, and nuclei in higher plants. Immunocytolocalization experiments with isozyme-specific antibodies indicate that both the chloroplastic and the cytosolic forms of the enzyme are present in the pea (Pisum sativum L.) leaf nucleus.Correspondence and reprints: Department of Biological Sciences m/c 066, University of Illinois–Chicago, 845 West Taylor, Chicago, IL 60607-7060, U.S.A.     

Positioning the genome within the nucleus

Higher eukaryotic genomes contain both housekeeping genes and genes of which the expression is restricted to a defined time and space. It is well established that a correlation exists between structural organization of the genome and gene expression control. The functional mechanisms underlying this correlation are still poorly understood. Here I describe several observations that are the basis of present concepts of genome organization and nuclear architecture related to functionality. Regarding the relationship between positioning and disturbed cell functionality, I describe observations showing that the proximity of selected gene loci is statistically correlated with their propensity for oncogenic translocations as well as observations of patterns occurring in neurodegenerative disorders where unstable repeats are translated into an expanded polyglutamine tract. Such observations underscore the importance to understand how genetic perturbations lead to the global reorganization of nuclear architecture, chromatin structure and widespread changes in gene expression.     

Tumor suppressor IRF-1 mediates retinoid and interferon anticancer signaling to death ligand TRAIL

Retinoids and interferons are signaling molecules with pronounced anticancer activity. We show that in both acute promyelocytic leukemia and breast cancer cells the retinoic acid (RA) and interferon signaling pathways converge on the promoter of the tumoricidal death ligand TRAIL. Promoter mapping, chromatin immunoprecipitation and RNA interference reveal that retinoid-induced interferon regulatory factor-1 (IRF-1), a tumor suppressor, is critically required for TRAIL induction by both RA and IFNgamma. Exposure of breast cancer cells to both antitumor agents results in enhanced TRAIL promoter occupancy by IRF-1 and coactivator recruitment, leading to strong histone acetylation and synergistic induction of TRAIL expression. In coculture experiments, pre-exposure of breast cancer cells to RA and IFNgamma induced a dramatic TRAIL-dependent apoptosis in heterologous cancer cells in a paracrine mode of action, while normal cells were not affected. Our results identify a novel TRAIL-mediated tumor suppressor activity of IRF-1 and suggest a mechanistic basis for the synergistic antitumor activities of certain retinoids and interferons. These data argue for combination therapies that activate the TRAIL pathway to eradicate tumor cells.     

Proteomic analysis of nuclear proteins from proliferative and differentiated human colonic intestinal epithelial cells

Self-renewing tissues such as the intestine contain progenitor proliferating cells which subsequently differentiate. Cell proliferation and differentiation involve gene regulation processes which take place in the nucleus. A human intestinal epithelial cell line model (Caco2/TC7) which reproduces these dynamic processes has been used to perform proteomic studies on nuclear proteins. Nuclei from Caco2/TC7 cells at proliferative and differentiated stages were purified by subcellular fractionation. After two-dimensional gel electrophoresis separation and ruthenium staining, 400 protein spots were detected by image analysis. Eighty-five spots corresponding to 60 different proteins were identified by matrix-assisted laser desorption/ionization mass spectrometry in nuclei from proliferative cells. Comparison of nuclear proteomes from proliferative or differentiated cells by differential display resulted in the identification of differentially expressed proteins such as nucleolin, hnRNP A2/B1 and hnRNP A1. By using Western blot analysis, we found that the expression and number of specific isoforms of these nuclear proteins decreased in differentiated cells. Immunocytochemistry experiments also showed that in proliferative cells nucleolin was distributed in nucleoli-like bodies. In contrast, hnRNPs A2/B1 and A1 were dispersed throughout the nucleus. This study of the nuclear proteome from intestinal epithelial cells represents the first step towards the establishment of a protein database which will be a valuable resource in future studies on the differential expression of nuclear proteins in response to physiological, pharmacological and pathological modulations.     

Turtle phylogeny: insights from a novel nuclear intron

Introns have gained considerable popularity as markers for molecular phylogenetics. However, no primers exist for a nuclear intron that amplifies across all turtles. Available data from morphology and mitochondrial DNA have not unambiguously resolved relationships within the superfamily Trionychoidea and the family Chelidae, which together form a large portion of extant turtle diversity. We tested the phylogenetic utility of a novel intron from the RNA fingerprint protein 35 (R35) as applied to these two areas of turtle systematics. We found the intron to be a single-copy locus that provides excellent resolving power for lineages among turtles, though problems with alignment made it impossible to infer deeper amniote relationships. Maximum parsimony and maximum likelihood both demonstrated the polyphyly of Trionychoidea and the reciprocal monophyly of Australian/New Guinea and South American chelid turtles. This is the first study to resolve such relationships with strong statistical support, and we suggest that R35 holds great promise for resolving additional persistent problems in the phylogeny of living turtles.     

First nuclear DNA C-values for 28 angiosperm genera

This paper reports first DNA C-values for 28 angiosperm genera. These include first DNA C-values for 25 families, of which 16 are monocots. Overall familial representation is 47.2 % for angiosperms, but is now much higher for monocots (75 %) and basal angiosperms (73.1 %) than for eudicots (38.7 %). Chromosome counts are reported for 22 taxa, including first records for six genera plus seven species. Unrepresented families will become increasingly enriched for monotypic taxa from obscure locations that are harder to access. Thus, completing familial representation for genome size for angiosperms may prove impossible in any short period, and progress towards this goal will become slower.     

Genetic Defects as Tumor Markers

Carcinogenesis is long-term multistep accumulation of defects of genes responsible for cell division, DNA repair, and apoptosis. The functions of these genes are known both for norm and for pathologies caused by their damage and resulting in asocial cell behavior. Owing to the recent progress in studying the mechanisms of carcinogenesis, some genetic defects may be considered from the applied point of view (as tumor markers rather than as pathogenetic factors) and employed in diagnostics. Thus detection of mutant alleles in biological fluids (e.g., beyond the tumor) suggests higher risk of carcinogenesis. Genetic defects are a new class of tumor markers and have a substantial diagnostic potential. In contrast to known protein markers (-fetoprotein, etc.) used in clinical practice, DNA markers are oncospecific (as these are in direct cause-and-effect relationships with carcinogenesis) and universal (as there is not a single tumor cell without a genetic defect). Analysis of DNA markers may be employed not only in diagnostics or tumor growth monitoring (assessment of treatment efficiency, early detection of recurrence or metastasis), but also (prospectively) in screening (tumor detection at the presymptomatic stage, identification of high-risk groups). Theoretical grounds, prospects, problems, and methods of this new field are considered.     

Interaction between calcium-free calmodulin and IQ motif of neurogranin studied by nuclear magnetic resonance spectroscopy

The interaction of Ca(2+)-free calmodulin (apoCaM) with the IQ motif corresponding to the calmodulin-binding domain of neurogranin has been studied by nuclear magnetic resonance (NMR) methods. The NMR spectra of uncomplexed apoCaM and apoCaM in complex with the IQ motif recorded at 750 MHz were studied and the backbone assignments of the protein in both forms were obtained by triple-resonance multidimensional NMR experiments. Chemical shift perturbations were used to map the binding surfaces. Only a single set of resonances was observed throughout the titration, indicating that the binding interaction is under fast exchange. Analysis of chemical shift changes indicates that (a) the main interaction and conformational changes occur in the C-terminal domain of calmodulin and (b) linker-1 (residues 40-44) between EF-1 and EF-2, linker-3 (residues 112-117) between EF-3 and EF-4, and the end of the alpha-helix H (residues 145-148) may be involved in the binding process. The dissociation constant (K(d)), estimated by fitting the chemical shift changes against the IQ peptide concentration, ranged from about 1.2 x 10(-5) to 8.8 x 10(-5) M. This result demonstrates that the interaction falls into the weak binding regime.