Ca2+-binding proteins in nuclei

Localization of chicken muscle FBPase in cardiomyocyte nuclei

Fructose 1,6-bisphosphatase (FBPase; EC 3.1.3.11) localization in cardiomyocyte nuclei has recently been investigated in mammals [FEBS Lett. 539 (2003) 51]. In this study, nuclear localization of FBPase in the cardiac muscle of the chicken was studied by immunohistochemistry and other methods. A result of the electron microscopic investigation was confirmed by immunoblotting analysis. Using MALDI Q-TOF mass spectrometry and Mascot program, the nuclear FBPase was identified as muscle chicken FBPase. FBPase activity in isolated cardiomyocyte nuclei was 5.9 mU/g. Nuclear FBPase was strongly inhibited by allosteric inhibitor AMP. I(0.5) for AMP was 0.16 microM and was the same as for the purified chicken muscle enzyme.

Nucleolin is a calcium-binding protein

We have purified a prominent 110-kDa protein (p110) from 1.6 M NaCl extracts of rat liver nuclei that appears to bind Ca2+. p110 was originally identified by prominent blue staining with 'Stains-All' in sodium dodecyl sulfate-polyacrylamide gels and was observed to specifically bind ruthenium red and 45Ca2+ in nitrocellulose blot overlays. In spin-dialysis studies, purified p110 saturably bound approximately 75 nmol Ca2+/mg protein at a concentration of 1 mM total Ca2+ with half-maximal binding observed at 105 microM Ca2+. With purification, p110 became increasingly susceptible to proteolytic (likely autolytic) fragmentation, although most intermediary peptides between 40 and 90 kDa retained "Stains-All", ruthenium red, and 45Ca2+ binding. N-terminal sequencing of intact p110 and a 70-kDa autolytic peptide fragment revealed a strong homology to nucleolin. Two-dimensional sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE)/IEF revealed autolysis produced increasingly acidic peptide fragments ranging in apparent pI's from 5.5 for intact p110 to 3.5 for a 40 kDa peptide fragment. Intact p110 and several peptide fragments were immunostained with a highly specific anti-nucleolin antibody, R2D2, thus confirming the identity of this protein with nucleolin. These annexin-like Ca2+-binding characteristics of nucleolin are likely contributed by its highly acidic argyrophilic N-terminus with autolysis apparently resulting in largely selective removal of its basic C-terminal domain. Although the Ca2+-dependent functions of nucleolin are unknown, we discuss the possibility that like the structurally analogous HMG-1, its Ca2+-dependent actions may regulate chromatin structure, possibly during apoptosis.

Cation-chromatin binding as shown by ion microscopy is essential for the structural integrity of chromosomes

Mammalian interphase and mitotic cells were analyzed for their cation composition using a three-dimensional high resolution scanning ion microprobe. This instrument maps the distribution of bound and unbound cations by secondary ion mass spectrometry (SIMS). SIMS analysis of cryofractured interphase and mitotic cells revealed a cell cycle dynamics of Ca2+, Mg2+, Na+, and K+. Direct analytical images showed that all four, but no other cations, were detected on mitotic chromosomes. SIMS measurements of the total cation content for diploid chromosomes imply that one Ca2+ binds to every 12.5-20 nucleotides and one Mg2+ to every 20-30 nucleotides. Only Ca2+ was enriched at the chromosomal DNA axis and colocalized with topoisomerase IIalpha (Topo II) and scaffold protein II (ScII). Cells depleted of Ca2+ and Mg2+ showed partially decondensed chromosomes and a loss of Topo II and ScII, but not hCAP-C and histones. The Ca2+-induced inhibition of Topo II catalytic activity and direct binding of Ca2+ to Topo II by a fluorescent filter-binding assay supports a regulatory role of Ca2+ during mitosis in promoting solely the structural function of Topo II. Our study directly implicates Ca2+, Mg2+, Na+, and K+ in higher order chromosome structure through electrostatic neutralization and a functional interaction with nonhistone proteins.

Fluorescence detection of calcium-binding proteins with quinoline Ca-indicator quin2

We have established a fluorescence method to detect calcium-binding proteins by making use of the quinoline Ca indicator quin2. Authentic calcium-binding proteins were subjected to sodium dodecyl sulfate-polyacrylamide gel electrophoresis and then electrophoretically transferred onto polyvinylidene difluoride membranes. Transfers were incubated with nonradioactive calcium ions, then with quin2 to detect the calcium-binding proteins as fluorescent bands by illumination with UV light. Calmodulin and parvalbumin of EF hand conformation calcium-binding type were clearly identified. Quin2 distinguished smooth muscle alpha-actinin from skeletal muscle alpha-actinin; the former was faintly fluorescent, having a low affinity for calcium ions. In whole myofibril preparations from skeletal muscles, troponin-C, connectin (titin), and nebulin were intensely fluorescent, being shown to have calcium-binding ability. The fluorescence method is an accurate, safe, and simple procedure to detect the binding of calcium ions to proteins following electrophoresis. The overlay technique described can be completed within 15 h and detects as little as 38 ng/well of troponin-C in the starting sample.

Structure-function relationships in the Ca(2+)-ATPase of sarcoplasmic reticulum: facts, speculations and questions for the future

Structural data on the Ca(2+)-ATPase of sarcoplasmic reticulum are integrated with kinetic data on Ca2+ transport. The emphasis is upon ATPase-ATPase interactions, the requirement for phospholipids, and the mechanism of Ca2+ translocation. The possible role of cytoplasmic [Ca2+] in the regulation of the synthesis of Ca(2+)-ATPase is discussed.

Differential decondensation of mitotic chromosomes during hypotonic treatment of living cells as a possible cause of G-banding: an ultrastructural study

The chromosomal ultrastructure of Chinese hamster cells treated with 0.075 M KCl - a solution ordinarily used for making preparations of spread chromosomes - was studied. The hypotonic treatment was shown to result in differential decondensation of chromosomes which consists in the uneven distribution of deoxyribonucleoprotein (DNP) fibrils along chromatids. Fixation of cells with methanol acetic acid causes an abrupt restructuring of chromosomes. However, the DNP preserves its uneven distribution along chromatids. As seen on ultra-thin sections of marker nucleolus organizer chromosomes, the densely packed regions may correspond to G-bands detected in the selfsame chromosomes by standard methods of differential staining. The results suggest that the capacity of chromosomes for differential staining is based on the different resistance of G- and R-bands to the decondensing action of hypotonic solutions on living cells.

The isolation of nuclear envelopes. Effects of thiol-group oxidation and of calcium ions

The effects of (a) oxidative cross-linking of protein thiol groups and (b) the presence or absence of Ca2+ ions on rat liver nuclear-envelope isolation were studied. Two envelope-isolation procedures were compared: a well characterized low-ionic-strength method and a recently developed high-ionic-strength method. The latter method seems preferable to the former in respect of lower intranuclear contamination of the envelopes, suppression of endogenous serine proteinase, and maintenance of high specific activities of envelope-associated enzymes. In both procedures, however, the presence of Ca2+ gave rise to a rapid, apparently irreversible, contamination of the envelopes by intranuclear material. This effect was half-maximal at 20 microM-Ca2+. In addition, the envelopes became contaminated with intranuclear material by a Ca2+-independent mechanism, apparently resulting from N-ethylmaleimide-sensitive intermolecular disulphide-bond formation. This oxidative process seemed to have two major kinetic components (half-life, t1/2, approx. 2 min and 10 min). In view of these findings, it is recommended that (i) for most purposes, nuclear envelopes be isolated by the newly developed high-ionic-strength procedure, (ii) irrespective of the method used, Ca2+-chelators be included in all the buffers, (iii) thiol-group oxidation be prevented or reversed during the procedure.

Improved detection of calcium-binding proteins in polyacrylamide gels

We refined the method of Schibeci and Martonosi (1980a) to enhance detection of calcium-binding proteins in polyacrylamide gels using 45Ca2+. Our efforts have produced a method which is shorter, has 40-fold greater sensitivity over the previous method, and will detect 'EF hand'-containing calcium-binding proteins in polyacrylamide gels below the 0.5 microgram level. In addition, this method will detect at least one example from every described class of calcium-binding protein, including lectins and gamma-carboxyglutamic acid containing calcium-binding proteins. The method should be useful for detecting calcium-binding proteins which may trigger neurotransmitter release.

Thermal diminution and augmentation of the retention of transportable rRNA in nuclear envelope-free nuclei

We have examined the effect of temperature on the rRNA transport from nuclei isolated from Tetrahymena after removal of both nuclear membranes and pore complexes by 1% Triton X-100. These nuclei export rRNA as precursor ribosomal ribonucleoprotein particles at both 28 degrees C and 8 degrees C which are qualitatively the same in terms of rRNA pattern, sedimentation coefficients and buoyant densities. At 8 degrees C, however, significantly fewer ribosomal ribonucleoprotein particles can be maximally exported than at 28 degrees C, though nuclei contain enough potentially transportable particles. These are increasingly released with increasing temperatures. Under conditions non-permissive for export, temperature elevation decreases the number of the potentially transportable ribosomal ribonucleoprotein particles in nuclei. Our data show: transportable ribosomal ribonucleoprotein particles inside nuclei are not 'free', but rather are subject to a complex temperature-sensitive retention: this retention is gradually diminished under export conditions and augmented under non-permissive export conditions with increasing temperatures. These retention mechanisms operate at an intranuclear level preceding the ribosomal ribonucleoprotein passage through the nuclear envelope pore complexes, i.e., the nuclear envelope regulates neither the number of potentially transportable ribosomal ribonucleoprotein particles in nuclei nor the number of those particles which can be maximally exported from nuclei at a given temperature. We suggest that these retention mechanisms involve temperature-sensitive domains of the nuclear matrix.