Vega is a rapidly rotating star.

Vega, the second brightest star in the northern hemisphere, serves as a primary spectral type standard. Although its spectrum is dominated by broad hydrogen lines, the narrower lines of the heavy elements suggested slow to moderate rotation, giving confidence that the ground-based calibration of its visible spectrum could be safely extrapolated into the ultraviolet and near-infrared (through atmosphere models), where it also serves as the primary photometric calibrator. But there have been problems: the star is too bright compared to its peers and it has unusually shaped absorption line profiles, leading some to suggest that it is a distorted, rapidly rotating star seen pole-on. Here we report optical interferometric observations that show that Vega has the asymmetric brightness distribution of the bright, slightly offset polar axis of a star rotating at 93 per cent of its breakup speed. In addition to explaining the unusual brightness and line shape peculiarities, this result leads to the prediction of an excess of near-infrared emission compared to the visible, in agreement with observations. The large temperature differences predicted across its surface call into question composition determinations, adding uncertainty to Vega's age and opening the possibility that its debris disk could be substantially older than previously thought.

Parvalbumin is expressed in normal and pathological human parathyroid glands.

The parathyroid glands are of major importance in calcium homeostasis. Small changes in the plasma calcium (Ca2+) concentration induce rapid changes in parathyroid hormone (PTH) secretion to maintain the extracellular Ca2+ levels within the physiological range. Extracellular Ca2+ concentration is continuously measured by a G-protein-coupled Ca2+-sensing receptor, which influences the expression and secretion of PTH. The mechanism of signal transduction from receptor sensing to PTH secretion is not well understood, but changes in PTH secretion are tightly linked to changes in the cytosolic Ca2+ concentration. Using immunohistochemistry and Western blot analysis, we detected the EF Ca2+ binding protein parvalbumin (PV) in normal and in hyperplastic and adenomatous human parathyroid glands. The strongest PV signal was present in chief cells and water clear cells, whereas in oxyphilic cells only a weak signal was observed. Immunohistochemistry and in situ hybridization of the PTH indicated a co-localization of PV and PTH in the same cell types. Because changes in the cytosolic Ca2+ concentration are believed to influence the process of PTH secretion, a possible role of PV as a modulator of this Ca2+ signaling is envisaged.

Calcium-binding proteins in Aplysia neurons.

1. Calcium (Ca)-binding proteins of neuronal ganglia and of single, identified neurons of the marine mollusk, Aplysia californica, were investigated. Using transblot/45Ca overlays two proteins, at Mr 45,000 and Mr 23,000, with a high Ca-binding ability were found. 2. Western blot analysis revealed that the protein at Mr 45,000 could be separated by 2D-PAGE into proteins with Mr 40,000 and Mr 43,000. The protein at Mr 40,000 immunocross-reacted with antisera directed against parvalbumin and rat calbindin D-28K, indicating a novel Ca-binding protein sharing common antigenic determinants for both proteins. 3. The protein at Mr 23,000 could be separated into a group of proteins with Mr 13,000-20,000 which showed a high degree of similarity to sarcoplasmatic calcium-binding proteins (SCP). 4. We further investigated the protein pattern of single, identified neurons of different electrical activity (bursting, beating, and silent) by 2D-PAGE. Major differences were found in the range of low Mr and low pI, where Ca-binding proteins are generally located. A protein at high concentrations characteristic for silent cells migrated at a position similar to crayfish SCP. 5. The results show that various Ca-binding proteins are characteristic for neurons in the Aplysia nervous system and support the idea that they may effect the electrical behavior of nerve cells.

Sarcoplasmic calcium-binding proteins in Aplysia nerve and muscle cells.

Muscle (body wall, buccal mass, heart) and neural tissue of the marine mollusc Aplysia californica was analysed for calcium-binding proteins using transblot/45Ca overlay, Western blotting and two-dimensional polyacrylamide gel electrophoresis, and several low molecular weight calcium-binding proteins were identified. Our results that Aplysia muscle contains an abundant protein with a M(r) of approximately 20,000 with strong 45Ca(2+)-binding ability and cross-reactivity to antibodies against the sarcoplasmic calcium-binding protein isoform II (SCP II) from Amphioxus. Immunocytochemical studies revealed that isoforms of SCP are distributed in a tissue-specific manner, SCP II-like protein is exclusively present in muscle fibres closely associated with the contractile machinery, whereas the isoform I (SCP I-like protein) is exclusively present in a subset of neurons, suggesting a function in their calcium regulation. In addition, a novel 45Ca(2+)-binding protein of M(r) 43,000, pl 4.7, was found in muscle and in neurons. A third protein of M(r) 40,000, pl 4.8, cross-reacts with anti-parvalbumin and anti-calbindin D-28K antibodies.

Inactivation of individual Ca(2+)-binding sites in the paired EF-hand sites of parvalbumin reveals asymmetrical metal-binding properties.

Previously a rat parvalbumin mutant protein PVF102W was constructed with a reporter Trp at position 102 in the middle of the hydrophobic center [Pauls, T. L., et al. (1993) J. Biol. Chem. 268, 20897-20903]. In the present study three new parvalbumin mutant proteins, derived from PVF102W and containing alterations at positions essential for Ca2+ binding in either one of the two Ca(2+)-binding sites (PV-CD and PV-EF) or in both (PV-CD/-EF), were expressed and purified. With the flow dialysis method it was established that both PV-CD and PV-EF bind 1 Ca2+ with affinity constants KCa of 1.1 x 10(7) and 3.2 x 10(6) M-1, respectively. Mg2+ binding, monitored by equilibrium gel filtration in the absence of Ca2+, showed that both mutants bind 1 Mg2+ with KMg = 8 10(4) for PV-CD and 3 x 10(3) M-1 for PV-EF. Compared to the parameters of the parent mutant PVF102W (two sites with equal affinities of 2.7 x 10(7) and 3 x 10(4) M-1 for Ca2+ and Mg2+, respectively), these data indicate that inactivation of the EF site, much more than of the CD site, impairs divalent cation binding. The binding of Ca2+ and Mg2+ is mutually exclusive, indicative of a Ca2+/Mg2+ mixed site. However, as for PVF102W, the KMg values obtained from the competition equation are approximately 40-fold lower than the affinities measured by direct binding. PV-CD/-EF binds neither Ca2+ nor Mg2+. Trp fluorimetry revealed that in the three mutant PVs the residue Trp-102 is deeply buried in the hydrophobic core.(ABSTRACT TRUNCATED AT 250 WORDS)

Chimeras of parvalbumin and oncomodulin involving exchange of the complete CD site show that the Ca2+/Mg2+ specificity is an intrinsic property of the site.

Rat parvalbumin (PV) and oncomodulin (OM) differ in the affinity and selectivity of metal binding to their CD site, which is a high-affinity Ca2+/Mg(2+)-mixed site in PV and a low-affinity Ca(2+)-specific site in OM. To assess to what degree the Ca2+/Mg2+ specificity and affinity of an EF-hand motif in a protein is intrinsically determined by its sequence, the complete CD sites were exchanged, yielding two chimeras, [S41-Q71]PV and [D41-S71]OM. The optical characteristics of a Trp102, inserted in the hydrophobic core of PV, OM and the two chimeras, are very similar in all four proteins, which suggests that the hydrophobic core is qualitatively similar in the chimeras as in the parent proteins. Direct Ca2+ and Mg2+ binding monitored by flow dialysis and gel filtration revealed that [S41-Q71]PV binds only one Mg2+ with an intrinsic affinity K'Mg2+ of 3.0 x 10(4) M-1 and two Ca2+ with an identical K'Ca2+ of 4.4 x 10(6) M-1, whereas [D41-S71]OM binds two Mg2+ with a mean K'Mg2+ of 2 x 10(4) M-1 and two Ca2+ with a K'Ca2+ of 1.3 x 10(7) M-1. K'Ca2+ of the CD site of [S41-Q71]PV was 2.5-fold higher than of the CD site in [W102]OM, but 5-6-fold lower than that of the CD site in [W102]PV. In [D41-S71]OM, K'Ca2+ of the CD site was twofold lower than in [W102]PV, but eightfold higher than in [W102]OM. These results indicate that the sequence of the CD site determines its Ca2+/Mg(2+)-specificity, whereas its affinity for Ca2+ influenced by the protein into which the CD site is inserted. The inserted CD site in turn influences the affinity of the EF site to which it is paired in the host protein and the paired sites display an equalized affinity for Ca2+. Mg2+ decreases the affinity of the chimeras for Ca2+, but not according to a simple competition model. The Mg2+ antagonism is much more pronounced in [D41-S71]OM than in [S41-Q71]PV, but in each chimera the CD and EF site are quantitatively affected in the same manner. Thus, [S41-Q71]PV which can only bind a single Mg2+ ion, displays a Ca2+/Mg(2+)-antagonism for both sites with a KMg.compet of 2.3 x 10(2) M-1. These results confirm the 'equalizer' principle in the cation-binding parameters of [S41-Q71]PV: both sites display the same Ca2+ affinity and Mg2+ antagonism. In [D41-S71]OM with its two Ca2+/Mg2+ sites the antagonism shows qualitatively the same complexity as in wild-type PV, although it is somewhat weaker in amplitude.

Site-specific replacement of amino acid residues in the CD site of rat parvalbumin changes the metal specificity of this Ca2+/Mg(2+)-mixed site toward a Ca(2+)-specific site.

Rat parvalbumin (PV) and oncomodulin (OM) display considerable sequence similarity and structural similarity, but differ in the affinity and selectivity of metal binding to their CD site, a Ca2+/Mg(2+)-mixed site in PV and a Ca(2+)-specific site in OM. In an attempt to identify the structural basis for these differences, mutations were introduced in the previously generated [W102]PV mutant, which contains a unique tryptophan as a conformational-sensitive fluorescent probe inside the hydrophobic core. In the present report, we substituted selected amino acid residues in the CD site of PV by those present at identical positions in OM. One mutant protein, named [F66, W102]PV, has one new substitution in which isoleucine at position 66 was exchanged by phenylalanine. The second mutant protein, [I46, I50, L58, F66, W102]PV, has four new substitutions, namely V46-->I, L50-->I, I58-->L and I66-->F. Tryptophan fluorescence and difference spectrophotometry indicated that the mutations do not alter significantly the hydrophobic core. Both mutant proteins display two metal-binding sites of identical affinities with intrinsic affinity constants K'Ca2+ of 2.9 x 10(7) M-1 for [F66, W102]PV and 1.7 x 10(7) M-1 for [I46, I50, L58, F66, W102]PV and K'Mg2+ of 3.1 x 10(4) M-1 for [F66, W102]PV and 1.9 x 10(4) M-1 for [I46, I50, L58, F66, W102]PV. Thus, the five-residue substitution, but not the two-residue one, leads to a small decrease of affinity compared to [W102]PV (K'Ca2+ = 2.7 x 10(7) M-1, K'Mg2+ = 4.4 x 10(4) M-1). Despite these similarities, the Mg2+ effect on Ca2+ binding is different for the two mutant parvalbumins: the Ca(2+)-binding isotherms of [F66, W102]PV undergo a parallel shift upon increasing Mg2+ concentrations, which indicates that the Mg2+ effect on the two Ca(2+)-binding sites is the same and quantitatively very similar to that described for [W102]PV. In [I46, I50, L58, F66, W102]PV, Mg2+ antagonizes the binding of the second Ca2+ (likely at the EF site) much more than that of the first Ca2+ (likely the CD site). According to the competition equation, the two sites display KMg2+.compet values of 390 M-1 and 3.9 x 10(3) M-1, respectively. These data indicate that (a) the single I66-->F mutation does not modify the cation binding parameters. (b) Multiple modifications in the hydrophobic core still do not change the affinity for Ca2+ and Mg2+, but strongly affect the Mg2+ antagonism and probably the selectivity of the CD site.

Changes in shape and motility of cells transfected with parvalbumin cDNA.

Parvalbumin is thought to act as a Ca2+ buffer in skeletal muscle fibers, but its physiological role in brain, kidney, and testis remains unclear. We have transfected parvalbumin cDNA into a human ovarian adenocarcinoma cell line, which normally does not express this protein. The induced expression of parvalbumin under the control of three different promoters causes: (1) changes in the morphology of the cells from epitheloid to fusiform, (2) an increase in motility of whole cell clusters, and (3) a decrease in the mitotic rate. Transfection with a mutated cDNA of rat parvalbumin incapable of binding Ca2+ had no effect on these three parameters. Our results indicate that ectopic expression of parvalbumin influences not only cell division [Rasmussen and Means (1989) Mol. Endocrinol. 3, 588-596], but also cell shape and motility by modulating intracellular Ca2+ handling. This may be a basic function of parvalbumin when it is intrinsically expressed in differentiated nonmuscle cells.

15N NMR relaxation studies of calcium-loaded parvalbumin show tight dynamics compared to those of other EF-hand proteins.

Dynamics of the rat alpha-parvalbumin calcium-loaded form have been determined by measurement of 15N nuclear relaxation using proton-detected heteronuclear NMR spectroscopy. The relaxation data were analyzed using spectral density functions and the Lipari-Szabo formalism. The major dynamic features for the rat alpha-parvalbumin calcium-loaded form are (1) the extreme rigidity of the helix-loop-helix EF-hand motifs and the linker segment connecting them, (2) the N and C termini of the protein being restricted in their mobility, (3) a conformational exchange occurring at the kink of helix D, and (4) the residue at relative position 2 in the Ca2+-binding sites having an enhanced mobility. Comparison of the Ca2+-binding EF-hand domains of alpha-parvalbumin-Ca2+, calbindin-Ca2+, and calmodulin-Ca2+ shows that parvalbumin is probably the most rigid of the EF-hand proteins. It also illustrates the dynamical properties which are conserved in the EF-hand domains from different members of this superfamily: (1) a tendency toward higher mobility of NH vectors at relative position 2 in the Ca2+-binding loop, (2) a restricted mobility for the other residues in the binding loop, and (3) an overall rigidity for the helices of EF-hand motifs. The differences in mobility between parvalbumin and the two EF-hand proteins occur mainly at the linker connecting the pair of EF hands and also at the C terminus of the last helix. In parvalbumin-Ca2+, these two regions are characterized by a pronounced rigidity compared to the corresponding more mobile regions in calbindin-Ca2+ and calmodulin-Ca2+.

Metal binding properties of recombinant rat parvalbumin wild-type and F102W mutant.

Rat parvalbumin (PV), an EF-hand type Ca(2+)-binding protein, was expressed in Escherichia coli and mutated by replacing a Phe at position 102 with a unique Trp in order to introduce a distinct fluorescent label into the protein. Mass spectroscopy and NMR data indicate that the recombinant wild-type (PVWT) and F102W mutant (PVF102W) proteins have the expected molecular weight and retain the native structure. Both proteins contain two non-cooperative Ca2+/Mg(2+)-binding sites with intrinsic affinity constants, KCa and KMg, of 2.4 +/- 0.9 x 10(7) M-1 and of 2.9 +/- 0.2 x 10(4) M-1, respectively, for PVWT, and KCa and KMg, of 2.7 +/- 1.1 x 10(7) M-1 and of 4.4 +/- 0.3 x 10(4) M-1, respectively, for PVF102W. Based on the highly similar metal binding properties of PVWT and PVF102W the latter protein was used to study cation-dependent conformational changes. Trp fluorescence emission and UV difference spectra of PVF102W indicated that the Trp residue at position 102 is confined to a hydrophobic core and conformationally strongly restricted. Upon Ca2+ or Mg2+ binding the structural organization of the region around the Trp is hardly affected, but there are significant changes in its electrostatic environment. The conformational change upon binding of Ca2+ and Mg2+, as monitored by UV difference spectrophotometry, increases linearly from 0 to 2 cations bound, indicating that the binding of both ions contributes equally to the structural organization in this protein.