Calcium and magnesium binding to rat parvalbumin

Ca2+ and Mg2+ binding to rat parvalbumin was measured by means of the fluorescent Ca2+ indicator fluo-3 using a method developed earlier [Eberhard, M. & Erne, P. (1991) Eur. J. Biochem. 202, 1333-1338]. We demonstrate that rat parvalbumin contains two equivalent Ca2+/Mg2+ binding sites and that Ca2+ and Mg2+ compete for the same sites. Dissociation constants (Kd) for Ca2+ and Mg2+ in Hepes buffer containing 150 mM K+ at 35 degrees C and pH 7.2 are 11.0 +/- 1.8 nM and 41 +/- 8 microM, respectively. At an ionic strength below 0.2 M, Kd values of Ca2+ binding to rat parvalbumin are approximately proportional to the ion concentration. Kd values of Ca2+ binding were found to be about fourfold larger in the presence of Na+ as compared with K+, indicating that Na+ distinctly influences Ca2+ binding to rat parvalbumin. Both Ca2+ and Mg2+ binding to parvalbumin are exothermic whereas Ca2+ and Mg2+ binding to fluo-3 are endothermic entropy-driven processes.

A comparative study of the calcium-binding proteins calbindin-D28K, calretinin, calmodulin and parvalbumin in the rat spinal cord

Comparison of the immunocytochemical localizations revealed distinct patterns of differential distribution and overlapping of calbindin-D28K (CB-D28K), calretinin (CR), calmodulin (CM) and parvalbumin (PV) in the rat spinal cord. In some areas, one of the four calcium-binding proteins (CBPs) appears to be predominant, for example, CB-D28K in lamina I and ependymal cells, PV at the inner part of laminae II, CR in laminae V and VI and CM in motoneurons of lamina IX. In other regions of the spinal cord, more than one CBPs was abundant. CB-D28K and CR were similarly distributed in lamina II and the lateral spinal and cervical nucleus; CM and PV were similarly abundant in the ventromedial dorsal horn, internal basilar and central cervical nucleus; CR and PV were similarly abundant in the ventromedial dorsal horn, internal basilar and central cervical nucleus; CR and PV were similarly heterogeneous in the gracile fasciculus from caudal to rostral spinal cord. In the sacral dorsal gray commissure, the distribution patterns of CR and PV were clearly complementary. The unilateral ganglionectomies resulted in a substantial reduction of CBP-like immunoreactivity (CBP-LI) in the dorsal columns and a reduction of CM- and PV-LI in the ventromedial dorsal horn. In the motor system, only CM labeled large motoneurons in lamina IX and CB-D28K lightly stained pyramidal tract. The apparent absence of CM-LI in the superficial dorsal horn is contradictory to the presence of a CM-dependent nitric oxide synthase in the region. These data indicate that most CBP-LI in the dorsal column pathway had primary afferent origin, while the superficial dorsal horn exhibited intrinsic CBP immunoreactivity. The differential and selective localizations of CBPs in the spinal cord suggest a role for these proteins in spinal nociceptive processing, visceral regulation and dorsal column sensory pathways.

Red-edge excitation fluorescence spectroscopy of proteins in reversed micelles

The dependence of fluorescence emission maxima of L-tryptophan and single-tryptophan-containing proteins (ribonuclease T1, melittin, and parvalbumin) on excitation wavelength has been studied in reversed micelle systems of sodium bis(2-ethyl-1-oxyl) sulfosuccinate (AOT). No effect of fluorescence maximum shift for different excitation wavelengths is observed for ribonuclease T1, in which a single tryptophan residue is located in the nonrelaxating, nonpolar protein interior. L-Tryptophan and the rest of the studied proteins, which contain single tryptophan residues exposed to the solvent, exhibit the dipolar relaxational processes of partly immobilized water molecules in micelles. This effect depends on the molar H2O/AOT ratio. Circular dichroism measurements prove that there have been no structural changes of the studied proteins in micellar systems. The results provide information about dynamic relaxational processes in proteins.

The three-dimensional profile method using residue preference as a continuous function of residue environment

In the 3-dimensional profile method, the compatibility of an amino acid sequence for a given protein structure is scored as the sum of the preferences of the residues for their environments in the 3D structure. In the original method (Bowie JU, Lüthy R, Eisenberg D, 1991, Science 253:164-170), residue environments were quantized into 18 discrete environmental classes. Here, amino acid residue preferences are expressed as a continuous function of environmental variables (residue area buried and fractional area buried by polar atoms). This continuous representation of residue preferences, expressed as a Fourier series, avoids the abrupt change of preference of residues in slightly different environments, as encountered in the original method with its 18 discrete environmental classes. When compared with the discrete 18-class representation of residue environments, this continuous 3D profile is found to be more sensitive in identifying sequences that fold into the profiled structure but share with it little sequence identity. The continuous 3D profile is also less sensitive to errors in environmental variables than is the discrete 3D profile. The continuous 3D profile can also be used to detect wrong folds or incorrectly modeled segments in an otherwise correct structure, as could the discrete 3D profile (Lüthy R, Bowie JU, Eisenberg D, 1992, Nature 356:83-85). Moreover, the progress of structure improvement during atomic refinement can also be monitored by examining the profile scores in a moving-window scan. Finally, by defining a functional form for profile scores, we open the way to profile atomic refinement in which an atomic structure adjusts to produce residue environments more compatible with the protein side chains.

Calcium-binding activity of nucleobindin mediated by an EF hand moiety

In a previous paper (Biochem. Biophys. Res. Commun. 187, 375-380, 1992), we reported cloning of a gene for nucleobindin (Nuc) from mouse and human. Nuc was identified as a secreted protein with DNA-binding properties. We noticed that Nuc includes two units of sequence similar to the EF hand motif, a calcium-binding motif, between a region rich in basic amino acids, which is presumably a DNA-binding site, and a leucine zipper which is a dimerization motif. In the present study, we examined the calcium-binding activity of Nuc. Mouse and human recombinant Nuc (rNuc), as well as two mutant rNuc proteins, were synthesized in Escherichia coli. Mouse and human rNuc and one mutant rNuc, in which the region from the second EF hand motif to the C-terminus had been deleted, all had calcium-binding activity. By contrast, another mutant rNuc in which both EF hand motifs had been deleted lacked this activity. Analysis by circular dichroism spectrometry indicated that addition of Ca2+ ions induces a structural change in Nuc, presumably an increase in the amount of alpha helix. However, addition of Ca2+ ions did not seem to cause any change in DNA-binding activity.

Characterization of parvalbumin cDNA clones and gene expression in normal and dystrophic mice of strain 129 ReJ

Parvalbumin is a calcium-binding protein found in fast-twitch skeletal muscles and selected cells in the brain. In several dystrophic mutants in the mouse, the parvalbumin content of skeletal muscles and brain is reduced and this deficiency appears to correlate with the inability of these mice to handle enhanced calcium uptake associated with the dystrophic process. In this study, two overlapping cDNA clones of 392 and 1268 base pairs were isolated from a mouse cDNA library in lambda gt11, characterized, and used as probes to study the involvement of the parvalbumin gene and its expression in various tissues of dystrophic mice of strain 129 ReJ. Southern blot analyses of restriction fragments of genomic DNA from normal and dystrophic mice indicate the same number and size of parvalbumin-specific gene fragments observed by other researchers, suggesting that the size of the Pva gene is the same in both normal and dystrophic mice of strain 129 ReJ. Northern blot analyses of total RNA from hind-limb muscles using cloned parvalbumin cDNA as probes revealed an abundant 800-nucleotide mRNA with lesser amounts of a 1000-nucleotide mRNA transcript in both normal and dystrophic mice of strain 129 ReJ. The amount of these mRNAs was reduced by 65-77% in dystrophic muscles preparations and was similar to the levels of beta-actin mRNA in these animals. These results suggest that parvalbumin gene expression is not down regulated in dystrophic mice of strain 129 ReJ.

Novel avian thymic parvalbumin displays high degree of sequence homology to oncomodulin

CPV3 is a novel avian parvalbumin. It displays an isoelectric point of 4.6, intermediate between that of avian thymic hormone (pI = 4.3) and the muscle parvalbumin isoform (pI = 5.2). Expression of CPV3, like that of avian thymic hormone (ATH), is restricted to the thymic stroma. However, the CPV3 content of chicken thymus tissue (120 micrograms/g tissue) is 4 times lower than that of ATH (500 micrograms/g tissue). The polymerase chain reaction (PCR) was used to gain access to the nucleotide sequence of CPV3. A 147-base pair fragment of the coding sequence, corresponding to residues 48-97, was amplified from total chicken cDNA using degenerate PCR primers. A RACE-PCR strategy was then used to extend the known sequence in both the 5' and 3' directions. The cDNA sequence thus obtained includes 671 base pairs. Primer extension analysis suggests that the cloned cDNA corresponds to a full-length transcript. Northern analysis of chicken mRNA indicates that the average CPV3 transcript is approximately 800 nucleotides in length, significantly smaller than the ATH message (approximately 1000 nucleotides). Southern analysis suggests the presence of a single CPV3 gene in the chicken genome. The translated nucleotide sequence, displaying 108 residues between the initiator and termination codons, is that of a beta-parvalbumin. The CPV3 sequence exhibits 58% identity with ATH and 52% identity with the chicken muscle isoform. Interestingly, CPV3 and the mammalian oncodevelopmental parvalbumin called oncomodulin are identical at 73 of 108 residues (68% identity). Correspondingly, flow-dialysis measurements with 45Ca2+ indicate that the Ca(2+)-binding domains are inequivalent, as in oncomodulin. The apparent dissociation constants, at pH 7.4 in 150 mM NaCl, are approximately 10 nM and 80 nM.

Refined crystal structure of rat parvalbumin, a mammalian alpha-lineage parvalbumin, at 2.0 A resolution

We present here the X-ray crystal structure of the rat alpha-parvalbumin from fast twitch muscle. This protein (M(r) 11.8 kDa) crystallizes in space group P2(1)2(1)2(1) with unit cell dimensions of a = 34.3 A, b = 55.0 A, c = 156.1 A and three molecules in the asymmetric unit. The protein structure was solved by the molecular replacement method and has been refined to a crystallographic R-factor [formula: see text] of 0.181 for all reflections with I/sigma(I) > or = 2 (I = intensity) between 8.0 and 2.0 A resolution. The molecules located most easily in the molecular replacement rotation function had lower overall thermal motion parameters and higher numbers of intermolecular crystal packing contacts. The overall fold of the polypeptide chain for the rat alpha-parvalbumin is similar to other known parvalbumin structures (root-mean-square deviations in alpha-carbon atom positions range from 0.60 to 0.87 A). There are two Ca(2+)-binding sites in parvalbumins, and there is some evidence for a third ion-binding site, adjacent to the CD site, in the rat species. The level of structural variability among the best-ordered regions of the three independent rat alpha-parvalbumin molecules in the crystallographic asymmetric unit is two to three times higher than the mean coordinate error (0.10 A), indicating flexibility in the molecule. Sequence differences between alpha and beta-lineage parvalbumins result in repacking of the hydrophobic core and some shifts in the protein backbone. The shifts are localized, however, and entire helices do not shift as rigid units.

A new approach to the design of stable proteins

We propose a simple algorithm to design a sequence which fits a given protein structure with a given energy. The algorithm is a modification of the Metropolis Monte Carlo scheme in sequence space with an evolutionary temperature which sets the energy scale. There is a one to one correspondence between this optimization scheme and the Ising model of ferromagnetism. This analogy implies that the design algorithm does not encounter multiple-minima problems and is very fast. The algorithm is tested by 'predicting' the primary structures of four proteins. In each case the calculated primary structures had statistically significant homology with the natural structures.

A local alignment method for protein structure motifs

A method for the comparison of protein three-dimensional substructures was developed. The method employs the double dynamic programming method of Taylor & Orengo but identifies multiple local alignments rather than a single global alignment. A modification based on the Smith Waterman algorithm for sequence alignment enables the automatic identification and growth of the most structurally similar local alignments irrespective of length and composition. The method can also be used in a search mode to match substructures. Roughly five minutes is required to find all Greek-key motifs in a protein of 100 residues. Two novel globin folds have been detected using the method, the antibiotic protein colicin A and diphtheria toxin, neither of which have any functional relationship to the globins.

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.

Heme binding to calmodulin, troponin C, and parvalbumin, as a probe of calcium-dependent conformational changes

Heme-CO binds to the active (calcium-bound) form of calmodulin (CaM), but not to the inactive form. Despite a similarity in structure of another calcium-binding protein, skeletal muscle troponin C, both the affinity and the spectral red-shift of the absorption of the heme group are greatly decreased for troponin C relative to calmodulin. Parvalbumin, another calcium-binding protein, shows a twofold greater affinity for heme-CO relative to CaM. Unlike calmodulin and troponin C, the affinity of parvalbumin for heme-CO is even greater in the absence of calcium. The affinity of the tryptic and thrombic fragments of CaM for heme-CO are decreased relative to the entire calmodulin. The binding of heme-CO is specific as demonstrated by the discrimination of the calmodulin, troponin C, and parvalbumin pockets. The interaction of heme-CO with active (calcium-bound) CaM is rapid (ms) as determined by stopped flow measurements. No difference in kinetics was observed for mixing inactive (calcium free) CaM with a solution of [heme-CO plus calcium], indicating that the calcium-binding step and subsequent change in protein conformation are rapid.

The contribution of the cell wall to a transmembrane calcium gradient could play a key role in Bacillus subtilis protein secretion

A weak Ca(2+)-binding site (Ka = 0.8 x 10(3) M-1, at pH 7) was identified in the mature part of levansucrase. An amino acid substitution (Thr-236-->Ile) in this site alters simultaneously the affinity for calcium, the folding transition and the efficiency of the secretion process of levansucrase. Moreover, the ability of the Bacillus subtilis cell wall to concentrate calcium ions present in the culture medium was studied. We confirm the results of Beveridge and Murray who showed that the concentration factor is about 100 to 120 times. This property preserves a high concentration of Ca2+ (> 2 mM) on the external side of the cytoplasmic membrane, even in the absence of further Ca2+ supplementation in the growth medium. Such local conditions allow the spontaneous unfolding-folding transition of levansucrase en route for secretion. Since several exocellular proteins of B. subtilis are calcium-binding proteins, we propose that the high concentration of calcium ion in the microenvironment of the cell wall may play a key role in the ultimate step of their secretion process.

Human alpha and beta parvalbumins. Structure and tissue-specific expression

alpha and beta parvalbumins are Ca(2+)-binding proteins of the EF-hand type. We determined the protein sequence of human brain alpha parvalbumin by mass spectrometry and cloned human beta parvalbumin (or oncomodulin) from genomic DNA and preterm placental cDNA. beta parvalbumin differs in 54 positions from alpha parvalbumin and lacks the C-terminal amino acid 109. From MS analyses of alpha and beta parvalbumins we conclude that parvalbumins generally lack posttranslational modifications. alpha and beta parvalbumins were differently expressed in human tissues when analyzed by immunoblotting and polymerase-chain-reaction techniques. Whereas alpha parvalbumin was found in a number of adult human tissues, beta parvalbumin was restricted to preterm placenta. The pattern of alpha parvalbumin expression also differs in man compared to other vertebrates. For example, in rat, alpha parvalbumin was found in extrafusal and intrafusal skeletal-muscle fibres whereas, in man, alpha parvalbumin was restricted to the muscle spindles. Different functions for alpha and beta parvalbumins are discussed.

Protein fold refinement: building models from idealized folds using motif constraints and multiple sequence data

A general solution to the problem of directly incorporating data from multiple sequence alignments into the construction of molecular models was approached through the calculation of an estimated pairwise distance based on conserved hydrophobicity. A scaling method was developed that allowed the required bulk geometric properties of the estimated pair-wise distances (mean and mean squared) to mimic those expected in a globular protein. These properties were maintained independently of the composition, length, number or degree of conservation of the original sequences. Despite being a poor estimate for individual distances were found to be compatible with the native structure and could be weighted highly. While the estimated distances provided a general drive towards hydrophobic packing, more specific structure (including secondary structures and motifs) were induced by regularization towards an ideal form. These constraints were used to refine an outline starting structure (derived only from secondary structure axes) towards a compact form that was sufficiently protein-like for side chains to be added with almost no further adjustment of the alpha-carbon positions. This process allows rough folds based on abstract representations of protein architecture to be rapidly converted to a form where they can be analysed by the growing number of methods designed to assess molecular models.

Excited states of tryptophan in cod parvalbumin. Identification of a short-lived emitting triplet state at room temperature

The fluorescence and phosphorescence spectra of model indole compounds and of cod parvalbumin III, a protein containing a single tryptophan and no tyrosine, were examined in the time scale ranging from subnanoseconds to milliseconds at 25 degrees C in aqueous buffer. For both Ca- bound and Ca-free parvalbumin and for model indole compounds that contained a proton donor, a phosphorescent species emitting at 450 nm with a lifetime of approximately 20-40 ns could be identified. A longer-lived phosphorescence is also apparent; it has approximately the same absorption and emission spectrum as the short-lived triplet molecule. For Ca parvalbumin, the decay of the long-lived triplet tryptophan is roughly exponential with a lifetime of 4.7 ms at 25 degrees C whereas for N-acetyltryptophanamide in aqueous buffer the decay lifetime was 30 microseconds. In contrast, the lifetime of the long-lived tryptophan species is much shorter in the Ca-free protein compared with Ca parvalbumin, and the decay shows complex nonexponential kinetics over the entire time range from 100 ns to 1 ms. It is concluded that the photochemistry of tryptophan must take into account the existence of two excited triplet species and that there are quenching moieties within the protein matrix that decrease the phosphorescence yield in a dynamic manner for the Ca-depleted parvalbumin. In contrast, for Ca parvalbumin, the tryptophan site is rigid on the time scale of milliseconds.

Structural fluctuations in proteins revealed by time-resolved fluorescence spectroscopy

Time-resolved fluorescence spectroscopy permits the direct assessment of proteins motions in the picosecond-nanosecond time-scaled, i.e., in a time-window compatible with observation of relevant motions of the protein matrix. The intrinsic fluorescence emission from tryptophan and tyrosine residues provides a convenient tool to follow these dynamic events in proteins. In the present investigation, the use of time-resolved fluorescence spectroscopy to monitor protein dynamics is illustrated by a study of the effects of temperature and calcium binding on the internal dynamics of the calcium-binding protein, parvalbumin, and by an investigation of the effects of hydration on the measurements of both fluorescence intensity and anisotropy decays provided complementary information regarding the flexibility of aromatic side chains in the proteins investigated, which could be correlated with environmental effects on protein structure.

Semi-automated chromatographic procedure for the isolation of acetylated N-terminal fragments from protein digests

Several published procedures have been combined to develop a general strategy for the specific identification and isolation of the acetylated-N-terminal fragment from all other proteolytic fragments. This ruse can be divided into four steps: (i) succinylation of the substrate to block lysine NH2 groups; (ii) enzymatic digestion of the modified protein; (iii) automated phenylisothiocyanate derivatization of the protease derived fragments to block newly generated "free" N-termini; and (iv) reversed-phase high-performance liquid chromatography with on-line photodiode array spectroscopy. The individual phenylthiocarbamyl-peptide species exhibit an increased reversed-phase retention time and a greater UV (210-297 nm) profile compared to the corresponding control (-phenylisothiocyanate) digest. The N-terminal acetylated fragment shows neither a retention time shift nor an augmented UV profile. To validate each process step, synthetic peptides and acetylated-N-terminal proteins of known sequence were used as test samples. The desired fragment was isolated from three proteins and positively identified by electrospray mass spectrometry and amino acid composition. Proteins with other N-terminal blocking groups should be amenable to this procedure.

Symmetrical rearrangement of the cation-binding sites of parvalbumin upon Ca2+/Mg2+ exchange. A study by 1H 2D NMR

Two forms of parvalbumin, i.e., the fully Ca-loaded form PaCa2 and the fully Mg-loaded form PaMg2, are investigated by 2D 1H NMR in solution. A detailed analysis of the resonances, which belong to residues involved in direct coordination of Ca2+ and Mg2+, establishes that the sixth ligand, a highly conserved Glu residue at the relative position 12 in both cation-binding sites CD and EF, undergoes a conformational rearrangement through a 120 degrees rotation of its side chain about the C alpha-C beta bond with PaMg2 adopting the less energetically favored g- conformation, as inferred from scalar coupling constants and dipole-dipole contacts measured on the COSY and NOESY spectra, respectively. Similarly, chemical shift effects, which selectively involve NH and C alpha H resonances (as well as side-chain resonances) in both CD and EF sites, point to a symmetrical behavior of both cation-binding sites upon Ca2+/Mg2+ exchange.

Evidence that deprotonation of serine-55 is responsible for the pH-dependence of the parvalbumin Eu3+ 7F0-->5D0 spectrum

The Eu(III)7F0-->5D0 excitation spectra of the parvalbumins are highly pH-dependent. Below pH 6.0, they exhibit a sharp, partially resolved doublet centered near 5,795 A. However, as the pH is raised, the spectrum becomes increasingly dominated by a much broader signal near 5,784 A. This behavior has been traced to the Eu(III) ion bound at the CD site, but the identity of the moiety undergoing deprotonation remains uncertain. Site-specific mutagenesis studies on the parvalbumin-like protein known as oncomodulin now suggest that the species in question is a liganding serine hydroxyl group. Specifically, replacement of serine-55 by aspartate (the residue present at the corresponding position in the EF site) affords a protein that retains two functional lanthanide binding sites, but fails to undergo the pH-dependent spectral alteration. By contrast, replacement of aspartate-59 by glycine (the corresponding EF site residue) fails to abolish the pH-dependent behavior.

Fine structure of rat septohippocampal neurons: I. Identification of septohippocampal projection neurons by retrograde tracing combined with electron microscopic immunocytochemistry and intracellular staining

In this report the normal dendritic organization and fine structure of identified septohippocampal projection neurons is described as a prerequisite for a time course analysis of retrograde changes in these neurons following axotomy (see Naumann et al., J. Comp. Neurol. 325:219-242, 1992). Septohippocampal projection neurons were retrogradely labeled by injection of the fluorescent tracer Fluoro-Gold into the hippocampus. Next, retrogradely labeled cells in Vibratome sections of the medial septum/diagonal band complex were intracellularly stained with the fluorescent dye Lucifer Yellow (LY). Photooxidation of LY resulted in a stable electron-dense reaction product, which allowed us to study these double-labeled neurons by electron microscopy. Another series of sections containing retrogradely labeled neurons were immunostained for choline acetyltransferase (ChAT) or parvalbumin (PARV). In this way the fine structure of two different chemically characterized subpopulations of septohippocampal neurons could be compared with that of the LY-injected neurons. Intracellular filling of retrogradely labeled neurons with LY stained the cell body and the entire dendritic arbor. Essentially, three classes of neurons could be distinguished, i.e., bipolar cells, multipolar neurons, and an intermediate group. All these neurons displayed smooth, often varicose dendrites lacking spines. Mainly located close to the midline, there was a group of cells with only very few if any LY-stained dendrites. In the electron microscope, the double-labeled neurons were easily identified by numerous electron-dense lysosomes associated with transported Fluoro-Gold and the diffuse reaction product resulting from photooxidation. They displayed fine-structural characteristics as previously described for cholinergic neurons. In fact, our fine-structural analysis of ChAT-positive Fluoro-Gold-labeled neurons, but also of back-filled PARV-positive cells, gave very similar results. All these neurons had infolded nuclei, abundant cytoplasmic organelles, and a few axosomatic synapses. Thus, a plain electron microscopic study does not allow one to distinguish between subpopulations of septohippocampal projection neurons.

Probing the metal-binding sites of cod parvalbumin using europium(III) ion luminescence and diffusion-enhanced energy transfer

Excitation spectroscopy of the 7F0----5D0 transition of Eu3+ and diffusion-enhanced energy transfer are used to study metal-binding characteristics of the calcium-binding protein parvalbumin from codfish. Energy is transferred from Eu3+ ions occupying the CD- and EF-binding sites to the freely-diffusing Co(III) coordination complex energy acceptors: [Co(NH3)6]3+, [Co(NH3)5H2O]3+, [CoF(NH3)5]2+, [CoCl(NH3)5]2+, [Co(NO2)3(NH3)3], and [Co(ox)3]3-. In the absence of these inorganic energy acceptors, the excited-state lifetimes of Eu3+ bound to the CD and EF sites are indistinguishable, even in D2O; however, in the presence of the positively charged energy acceptor complexes, the Eu3+ probes in the cod parvalbumin have different excited-state lifetimes due to a greater energy-transfer site from Eu3+ in the CD site than from this ion in the EF site. The observation of distinct lifetimes for Eu3+ in the two sites allows the study of the relative binding site affinities and selectivity, using other members of the lanthanide ion series. Our results indicate that during the course of a titration of the metal-free protein, Eu3+ fills the two sites simultaneously. Eu3+ is competitively displaced by other Ln3+ ions, with the CD site showing a preference for the larger Ln3+ ions while the EF site shows little, if any, competitive selectivity across the Ln3+ ion series.

Circularly polarized luminescence from terbium(III) as a probe of metal ion binding in calcium-binding proteins

A number of different experimental techniques have been used to probe the details of structural changes on the binding of Ca(II) to the large number of known calcium-binding proteins. The use of luminescent lanthanide(III) ions, especially terbium(III) and europium(III), as substitutional replacement for calcium(II), has led to a number of useful experiments from which important details concerning the metal ion coordination sites have been obtained. This work is concerned with the measurement of the circularly polarized luminescence (CPL) from the 5D4----7F5 transition of Tb(III) bound to the calcium binding sites of bovine trypsin, bovine brain calmodulin, and frog muscle parvalbumin. It is demonstrated that it is possible to make these polarization measurements from very dilute solutions (less than 20 microM) and monitor structural changes as equivalents of Tb(III) are added. It is shown that the two proteins that belong to the class of "EF-hand" structures (calmodulin and parvalbumin) possess quite similar CPL line shapes, whereas Tb(III) bound to trypsin has a much different band structure. CPL results following competitive and consecutive binding of Ca(II) and Tb(III) bound to calmodulin are also reported and yield information concerning known differences between the sequence of binding of these two species.