OCP1, an F-box protein, co-localizes with OCP2/SKP1 in the cochlear epithelial gap junction region.

Immunohistochemical data indicate that OCP1 co-localizes exactly with OCP2 in the epithelial gap junction region of the guinea pig organ of Corti (OC). Despite the abundance of OCP1 in the OC, gaining access to its coding sequence -- and, in particular, the 5' end of the coding sequence -- proved unexpectedly challenging. The putative full-length OCP1 cDNA -- 1180 nucleotides in length -- includes a 67 nucleotide 5' leader sequence, 300 codons (including initiation and termination signals), and a 216 nucleotide 3' untranslated region. The cDNA encodes a protein having a predicted molecular weight of 33,700. The inferred amino acid sequence harbors an F-box motif spanning residues 52--91, consistent with a role for OCP1 and OCP2 in the proteasome-mediated degradation of select OC proteins. Although OCP1 displays extensive homology to an F-box protein recently cloned from rat brain (NFB42), clustered sequence non-identities indicate that the two proteins are transcribed from distinct genes. The presumptive human OCP1 gene was identified in the human genome databank. Located on chromosome 1p35, the inferred translation product exhibits 94% identity with the guinea pig OCP1 coding sequence.

The dihydrolipoyl acyltransferase (BCE2) subunit of the plant branched-chain alpha-ketoacid dehydrogenase complex forms a 24-mer core with octagonal symmetry.

Little is known of the plant branched-chain alpha-ketoacid dehydrogenase complex. We have undertaken a detailed study of the structure of the dihydrolipoyl acyltransferase (BCE2) subunit that forms the core of the complex, to which two other enzymes attach. Mature Arabidopsis thaliana BCE2 was expressed in Escherichia coli. The soluble recombinant protein was purified using a Superose 6 size-exclusion column to >90% homogeneity and was catalytically active. The recombinant protein formed a stable complex with a native molecular mass of 0.95 MDa and an S coefficient of 19.4, consistent with formation of a 24-mer. Negative-staining transmission electron microscopy of the recombinant protein confirmed that BCE2 forms a core with octagonal symmetry. Despite divergence of mammalian and plant BCE2s, there is clearly conservation of structure that is independent of primary sequence.

Influence of monovalent cations on rat alpha- and beta-parvalbumin stabilities.

The mammalian genome encodes both alpha- and beta-parvalbumin isoforms. The rat beta-parvalbumin (aka "oncomodulin") is more stable than the alpha isoform at physiological pH and ionic strength, despite its substantially higher charge density and truncated C-terminal helix [Henzl, M. T., and Graham, J. S. (1999) FEBS Lett. 442, 241-245]. Reasoning that solvent interactions could contribute to this unexpected finding, we have examined the stabilities of the Ca(2+)-free alpha- and beta-parvalbumins as a function of Na(+) and K(+) concentration. Differential scanning calorimetry data suggest that, at physiological pH and ionic strength, the beta isoform binds roughly 2 equiv of Na(+) or a single equivalent of K(+) with moderate affinity. Under comparable conditions, the alpha isoform apparently binds just 1 equiv of Na(+) and essentially no K(+). Isothermal titration calorimetry experiments suggest that the bound monovalent ions occupy the EF-hand motifs. In 0.15 M K(+), at pH 7.4, the stability of the apo-beta-parvalbumin exceeds that of the alpha isoform by approximately 2.6 kcal/mol at 37 degrees C and by approximately 3.0 kcal/mol at 25 degrees C. The latter value represents a substantial fraction of the difference in Ca(2+)-binding free energies measured in vitro for the two proteins. Significantly, however, these results do not completely explain the paradoxical stability of the beta isoform, which maintains its higher melting temperature under all conditions examined.

Conformational stabilities of the rat alpha- and beta-parvalbumins.

It is widely believed that beta-parvalbumin (PV) isoforms are intrinsically less stable than alpha-parvalbumins, due to greater electrostatic repulsion and an abbreviated C-terminal helix. However, when examined by differential scanning calorimetry, the apo-form of the rat beta-PV (i.e. oncomodulin) actually displays greater thermal stability than the alpha-PV. Whereas the melting temperature of the a isoform is 45.8 degrees C at physiological pH and ionic strength, the Tm for the beta isoform is more than 7 degrees higher (53.6 degrees C). This result suggests that factors besides net charge and C-terminal helix length strongly influence parvalbumin conformational stability. Extension of the F helix in the beta-PV, by insertion of Ser-109, has a modest stabilizing effect, raising the Tm, by 1.1 degrees. Truncation of the alpha-PV F helix, by removal of Glu-108, has a more profound impact, lowering the Tm by 4.0 degrees.

Interconversion of the ligand arrays in the CD and EF sites of oncomodulin. Influence on Ca2+-binding affinity.

The parvalbumin metal ion-binding sites differ at the +z and -x residues: Whereas the CD site employs serine and glutamate (or aspartate), respectively, the EF site employs aspartate and glycine. Although frequently indistinguishable in Ca2+- and Mg2+-binding assays, the CD and EF sites nonetheless exhibit markedly different preferences for members of the lanthanide series [Williams et al. (1984) J. Am. Chem. Soc. 106, 5698-5702], underscoring an intrinsic nonequivalence. This nonequivalence reaches its pinnacle in the mammalian beta-parvalbumin (oncomodulin). Whereas the oncomodulin EF site exhibits the expected Ca2+/Mg2+ signature, the Ca2+ affinity of the CD site is severely attenuated. To obtain insight into the structural factors responsible for this reduction in binding affinity, oncomodulin variants were examined in which the CD and EF site ligand arrays had been exchanged. Our data suggest that binding affinity may be dictated either by ligand identity or by the binding site environment. For example, the Ca2+ affinity of the quasi-EF site resulting from the combined S55D and D59G mutations is substantially lower than that of the authentic EF site. This finding implies that other local environmental variables (e.g., binding loop flexibility, electrostatic potentials) within the CD binding site supersede the influence of ligand identity. However, the CD site ligand array does not acquire a high-affinity signature when imported into the EF site, as in the D94S/G98D variant. Instead, it retains its Ca2+-specific signature, implying that this constellation of ligands is less sensitive to placement within the protein molecule. The D59G and D94S single mutations substantially lower binding affinity, consistent with removal of a liganding carboxylate. By contrast, the S55D and G98D mutations substantially increase binding affinity, a finding at odds with corresponding data collected on model peptide systems. Significantly, the Ca2+ affinity of the oncomodulin CD site is increased by mutations that weaken binding at the EF site, indicating a negatively cooperative interaction between the two sites.

OCP2 exists as a dimer in the organ of Corti.

OCP2 is one of the most abundant proteins in the organ of Corti (OC), comprising approximately 5% of the total protein in the supporting cell population. Although the very close homolog, Skp1p, has been implicated in regulating cell-cycle progression, the function of OCP2 in the terminally differentiated cochlea is presently unknown. We have purified recombinant OCP2 from Escherichia coli and examined the protein by analytical ultracentrifugation. Interestingly, sedimentation equilibrium data collected at 20 degrees C unequivocally indicate that, at the concentrations present in the OC, free OCP2 would exist as a dimeric species. The apparent sedimentation coefficient is independent of concentration at loading concentrations between 10 and 100 microM, indicating the absence of a significant monomer-dimer equilibrium in this concentration range. The functional significance of this finding is discussed.

Oncomodulin is expressed exclusively by outer hair cells in the organ of Corti.

Oncomodulin (OM) is a small, acidic calcium-binding protein first discovered in a rat hepatoma and later found in placental cytotrophoblasts, the pre-implantation embryo, and in a wide variety of neoplastic tissues. OM was considered to be exclusively an oncofetal protein until its recent detection in extracts of the adult guinea pig's organ of Corti. Here we report that light and electron microscopic immunostaining of gerbil, rat, and mouse inner ears with a monoclonal antibody against recombinant rat OM localizes the protein exclusively in cochlear outer hair cells (OHCs). At the ultrastructural level, high gold labeling density was seen overlying the nucleus, cytoplasm, and the cuticular plate of gerbil OHCs. Few, if any, gold particles were present over intracellular organelles and the stereocilia. Staining of a wide range of similarly processed gerbil organs failed to detect immunoreactive OM in any other adult tissues. The mammalian genome encodes one alpha- and one beta-isoform of parvalbumin (PV). The widely distributed alpha PV exhibits a very high affinity for Ca2+ and is believed to serve as a Ca2+ buffer. By contrast, OM, the mammalian beta PV, displays a highly attenuated affinity for Ca2+, consistent with a Ca2+-dependent regulatory function. The exclusive association of OM with cochlear OHCs in mature tissues is likely to have functional relevance. Teleological considerations favor its involvement in regulating some aspect of OHC electromotility. Although the fast electromotile response of OHCs does not require Ca2+, its gain and magnitude are modulated by efferent innervation. Therefore, OM may be involved in mediation of intracellular responses to cholinergic stimulation, which are known to be Ca2+ regulated. (J Histochem Cytochem 46:29-39, 1998)

Oncomodulin is abundant in the organ of Corti.

A small, acidic Ca(2+)-binding protein (CBP-15) was recently detected in extracts of the mammalian auditory receptor organ, the organ of Corti [Senarita et al. (1995) Hear. Res. 90, 169-175]. N-terminal sequence data for CBP-15 [Thalmann et al. (1995) Biochem. Biophys. Res. Commun. 215, 142-147] implied membership in the parvalbumin family and possible identity with the mammalian beta-parvalbumin oncomodulin. As shown herein, the latter conclusion is supported by strong cross-reactivity between CBP-15 and isoform-specific antibodies to oncomodulin. Moreover, we have succeeded in amplifying the guinea pig CBP-15 coding sequence from organ of Corti cDNA using degenerate oligonucleotide primers based on the rat oncomodulin sequence. The deduced amino acid sequence of guinea pig CBP-15 displays 90%, 92%, and 98% identity with mouse, rat, and human oncomodulin isoforms. Demonstration of the presence of oncomodulin in the organ of Corti is the first documentation of this substance in a postnatal mammalian tissue.

Specific proteins of the organ of Corti.

The mammalian organ of Corti has achieved a degree of perfection unequaled in other hair cell systems. Although cellular metabolism requires the coordinated action of thousands of proteins, the physical processes underlying auditory transduction in the OC are undoubtedly mediated by a much smaller subset of these. OCP1, OCP2, and CBP-15-identified by 2D-PAGE-are apparently members of this elite class. OCP1 and OCP2 are restricted to the supporting cells of the organ of Corti and adjacent epithelia. Their distribution closely parallels the boundaries of the epithelial gap junction system, implying a role in cochlear potassium and pH homeostasis. CBP-15 was recently shown to be identical to oncomodulin, the mammalian beta-parvalbumin, heretofore documented only in the placenta and neoplasms. Expression of this small calcium-binding protein in the OC is restricted to the outer hair cells, where it may function as a calcium-dependent regulatory protein.

Introduction of a fifth carboxylate ligand heightens the affinity of the oncomodulin CD and EF sites for Ca2+.

The acid-pair hypothesis, proposed by Reid and Hodges [(1980) J. Theor. Biol. 84, 401-444], suggests that the affinity of an EF-hand motif for Ca2+ will be maximal with four acidic ligands, paired along the +x, -x and +z, -z axes. Addition of a fifth anionic ligand is predicted to reduce Ca(2+)-binding affinity, as a consequence of increased electrostatic repulsion. Interestingly, for oncomodulin, we observe that introduction of a fifth carboxylate residue at the +z position in the CD coordination sphere or at the -x position in the EF coordination sphere significantly increases the affinity of those sites for Ca2+. The variants resulting from replacement of serine-55 by aspartate (S55D), glycine-98 by aspartate (G98D), and the combined mutations (55/98) have been examined in Ca(2+)- and Mg(2+)-binding studies, titration calorimetry, and differential scanning calorimetry. The KCa for the CD site is reduced from 800 to 67 nM by the S55D mutation, while KCa for the EF site is reduced from 45 to 4 nM by the G98D mutation. Both mutations destabilize the apo form of the protein and increase the thermal stability on the Ca(2+)-bound state. Interestingly, the S55D mutation also increases the affinity of the oncomodulin CD site for Mg2+, decreasing the dissociation constant from > 1 mM to approximately 30 microM. This increase in affinity is reflected in a substantially increased thermal stability of the Mg(2+)-bound form of the protein. In 0.15 M NaCl, 0.025 M Hepes (pH 7.4), and 0.01 M Mg2+, the wild-type protein denatures at 68.5 degrees C. By contrast, under identical conditions, the S55D mutations denatures at 79.0 degrees C. The increased metal ion-binding affinity displayed by the variant proteins may result in part from preferential destabilization of the apo-protein by the additional carboxylate.

Intrathymic distribution of the two avian thymic parvalbumins.

Although parvalbumins are generally viewed as intracellular Ca2- buffers/transporters, avian species express two thymus-specific isoforms that may play alternative biological roles. These proteins, known as avian thymic hormone (ATH) and chicken parvalbumin 3 (CPV3), are conjectured to influence thymopoiesis. In this paper, we compare their intrathymic distributions. Isoform-specific monoclonal antibodies against ATH and CPV3 were labeled with fluorescein and Cy5, respectively, and then used to probe paraffin sections of chicken thymus tissue. Confocal microscopy of the stained sections reveals that ATH and CPV3 are both confined to the thymic cortex and that they are frequently coexpressed by a subset of epithelial cells. However, their expression patterns are not completely superimposible. Cortical epithelial cells are also observed that stain for just one of the two avian parvalbumin isoforms, albeit at lower frequency. Significantly, a subset of cortical thymocytes exhibits peripheral staining for one or both of the proteins. This result may imply the existence of plasma membrane receptors for the two proteins on select T-cell precursors. Alternatively, it may signal low level expression of the thymic parvalbumins by the thymocytes population.

Self-association of CPV3, an avian thymic parvalbumin.

The avian parvalbumin called CPV3 readily forms disulfide-linked oligomers. Sedimentation data presented herein reveal that CPV3 also undergoes noncovalent self-association. Interestingly, the noncovalent interaction is promoted by either Ca2+ or Mg2+, whereas covalent complex formation displays an absolute requirement for the Ca(2+)-bound protein. Apo-CPV3 exhibits an apparent sedimentation coefficient of 2.08 S at 20 degrees C, in 0.15 M NaCl, 0.025 M HEPES-NaOH, pH 7.4. This value increases to 2.85 S or 3.16 S with addition of 1.0 mM Ca2+ or 5.0 mM Mg2+, respectively. Least-squares analysis of sedimentation equilibrium data suggests that 100 microM apo-CPV3 is primarily a mixture of monomeric and dimeric forms. With the addition of Ca2+, the equilibrium becomes exclusively monomer-trimer, with negligible amounts of dimer. A comparable distribution is observed in the presence of Mg2+.

Detection of a beta-parvalbumin isoform in the mammalian inner ear.

A small, acidic calcium-binding protein (CBP-15) has been detected in the guinea pig organ of Corti, the auditory receptor organ. The apparent molecular weight (15,000) and very low isoelectric point (pI approximately 3.1) suggest that CBP-15 is a beta-parvalbumin isoform. Consistent with this hypothesis, CBP-15 exhibits extreme homology to the mammalian oncofetal parvalbumin called oncomodulin. Sequence data have now been obtained for 30 residues in the N-terminal third of CBP-15. Identity with oncomodulin is observed at all 30 positions. This finding could necessitate revision of the assumption that postnatal mammals utilize a single alpha-parvalbumin isoform in muscle and nonmuscle settings alike.

Interconversion of the CD and EF sites in oncomodulin. Influence on the Eu3+ 7F0-->5D0 excitation spectrum.

The appearance of the parvalbumin Eu3+ 7F0-->5D0 spectrum is markedly pH dependent, the result of a hitherto unidentified deprotonation event in the CD ion-binding domain [Treviño, C.L., et al. (1991) J. Biol. Chem. 265, 9694-9700]. We are studying this phenomenon in the mammalian placental parvalbumin called oncomodulin. As in other parvalbumins, the liganding residues in the CD and EF sites of oncomodulin differ at the +z and -x coordination positions: serine and aspartate, respectively, in the CD site; aspartate and glycine in the EF site. We have prepared a series of oncomodulin variants in which the +z and/or -x residue(s) from one site have been replaced by the corresponding residue(s) from the other. We herein characterize the resulting proteins by Eu3+ luminescence spectroscopy. Simultaneous replacement of serine-55 by aspartate and aspartate-59 by glycine affords the CD site with a coordination sphere superficially equivalent to that of the EF site. As observed previously for the S55D mutation [Henzl, M. T., et al. (1992) FEBS Lett. 314, 130-134], the Eu3+ 7F0-->5D0 spectrum of the 55/59 variant is pH independent. Interestingly, replacement of aspartate-94 by serine at the +z position of the EF site of 55/59 imparts pH dependent behavior to the EF site. The identical mutation in the wild-type background likewise imparts pH dependence to the EF site, affording a protein in which both sites display broad signals near 578.2 nm at pH 8. Significantly, a variant in which threonine replaces serine-55 retains the pH dependent spectroscopic signature. These results indicate that the presence of a hydroxyl group at the +z position is sufficient to confer pH dependence on the 7F0-->5D0 spectrum of a parvalbumin EF-hand domain. Importantly, the data also suggest that the component peaks of the low-pH doublet are not site-specific signals, as previously believed. Rather, they probably represent differences in coordination environment arising from differential hydration or conformational heterogeneity. In wild-type oncomodulin, the CD site signal dominates the low-pH spectrum. Since this dominance persists even when serine-55 and aspartate-59 are replaced by the corresponding EF site residues, it appears that the context of the CD binding site, as dictated by the global polypeptide fold, exerts a major influence on the metal ion-binding properties of the site.

Oligomerization of an avian thymic parvalbumin. Chemical evidence for a Ca(2+)-specific conformation.

CPV3, the third parvalbumin isoform to be identified in the chicken, is produced exclusively in the thymus gland. Although parvalbumins are typically cysteine-deficient, CPV3 contains two cysteine residues, at positions 18 and 72. The reported three-dimensional parvalbumin structures suggest that the side chain of cysteine-72 should be solvent-accessible. Accordingly, we find that CPV3 readily forms disulfide-linked oligomers in the absence of reducing agents. The reaction, employing either O2 or ferricyanide ion as the oxidant, is apparently restricted to the Ca(2+)-bound form of the protein. The differing reactivity of the Ca2+, Mg2+, and apo-forms has significant structural implications.

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.

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.

The structure of a Phaseolus vulgaris cDNA encoding the iron storage protein ferritin.

A cDNA containing the entire coding region for the iron storage protein ferritin has been isolated from the French bean plant, Phaseolus vulgaris L. cv. Tendergreen. Ferritin protein was purified from young leaves and shoot meristem tissue and used to raise antisera in mice. A lambda gt11 cDNA library was constructed from seed-derived poly(A)+ RNA, and screened with the mouse anti-ferritin serum. A 1.2 kb immunopositive phage DNA insert was isolated and sequenced. The derived amino acid sequence shows substantial similarity with other ferritin sequences. The 5' untranslated region contains two out-of-frame AUG codons, a region of extreme pyrimidine composition bias and potentially stable secondary structure.

Identification of a novel parvalbumin in avian thymic tissue.

A novel calcium-binding protein has been isolated from chicken thymus tissue. Its molecular weight (approximately 11,500) and characteristic interactions with Tb3+ and Eu3+ identify the protein as a member of the parvalbumin family. Electrophoretically distinct from both chicken (muscle) parvalbumin and avian thymic hormone, it represents the third parvalbumin to be identified in avian tissues and the second to be identified in the avian thymus gland.

Interactions between residues in the oncomodulin CD domain influence Ca2+ ion-binding affinity.

Despite striking sequence homology with rat parvalbumin, oncomodulin exhibits much lower affinity for Ca2+ ion. We are attempting to identify the structural basis for this difference by systematically substituting the parvalbumin residue for the oncomodulin residue at points of nonidentity. In this paper, we examine two mutations in the helical segments flanking the CD ion-binding loop. Replacement of Asp-45 in the C helix by lysine, to produce D45K, reduces the dissociation constant for Ca2+ at the CD site from 0.81 to 0.53 microM. Replacement of Lys-69 in the D helix by glycine, to afford K69G, similarly reduces KCa to 0.59 microM. Both mutations perturb the Eu3+ 7Fo----5Do spectral parameters. We also examine the consequences of simultaneous mutations involving positions 57, 59, 60, and 69. Ca(2+)-binding assays and Eu3+ luminescence measurements indicate that there is a conformational interaction between residues 57 and 69 and that this interaction is modulated by residues 59 and 60. When the mutations at positions 57, 59, 60, and 69 are combined, the resulting variant exhibits a KCa value for the CD site of 0.25 microM, reflecting a 3-fold increase in affinity relative to the wild-type protein. Moreover, the pK alpha governing the interconversion of low and high pH forms of the Eu3+ 7Fo----5Do spectrum is increased to 8.1, very close to the value of 8.25 determined previously for rat parvalbumin. In this paper, we also complete our survey of single mutations in the CD loop by examining L58I. Replacement of Leu-58 by isoleucine reduces the affinity of the CD site for Ca2+, raising KCa to 2.2 microM. Finally, we revise our previous estimate of the KCa value for Y57F downward, from 0.80 to 0.64 microM. The earlier result is believed to have been inflated by heterogeneity in the preparation, a consequence of proteolysis.