Calcium-dependent complex assembly of the myeloic differentiation proteins MRP-8 and MRP-14

MRP-8 and MRP-14 are calcium-binding proteins belonging to the S-100 protein family which have been shown to be associated with specific stages of myeloic/monocytic cell differentiation. Members of this protein family are shown to form homo- and heterodimers. Complex formation has also been observed in preliminary experiments for MRP-8 and MRP-14. To evaluate the in vivo relevance of the MRP complex formation and the stoichiometric ratio of individual components complexes were isolated from granulocytes and monocytes by immunoaffinity chromatography using monospecific antibodies. The purified fraction of the MRPs was found to contain monomers and dimers as shown on sodium dodecyl sulfate-polyacrylamide gel electrophoresis by silver staining and immunoblotting. Similar results were obtained by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and immunoblotting of crude cell extracts. The existence of the MRP complexes in vivo was demonstrated by chemical cross-linking and subsequent isolation of complexes by immunoaffinity chromatography. Two new, highly abundant complexes were found in addition to the heterodimer, but neither monomers nor homodimers were detected. The two larger protein complexes (35.0 and 48.5 kDa) were identified as [MRP-8)2.(MRP-14] trimer and [MRP-8)2.(MRP-14)2) tetramer, respectively. All complexes could be shown to be noncovalently associated in vivo. Furthermore, the association of MRPs was shown to be Ca2+ dependent.     

Myeloid cell function in MRP-14 (S100A9) null mice

Myeloid-related protein 14 (MRP-14) and its heterodimeric partner, MRP-8, are cytosolic calcium-binding proteins, highly expressed in neutrophils and monocytes. To understand the function of MRP-14, we performed targeted disruption of the MRP-14 gene in mice. MRP-14(-/-) mice showed no obvious phenotype and were fertile. MRP-8 mRNA but not protein is present in the myeloid cells of these mice, suggesting that the stability of MRP-8 protein is dependent on MRP-14 expression. A compensatory increase in other proteins was not detected in cells lacking MRP-8 and MRP-14. Although the morphology of MRP-14(-/-) myeloid cells was not altered, they were significantly less dense. When Ca(2+) responses were investigated, there was no change in the maximal response to the chemokine MIP-2. At lower concentrations, however, there was reduced responsiveness in MRP-14(-/-) compared with MRP-14(+/+) neutrophils. This alteration in the ability to flux Ca(2+) did not impair the ability of the MRP-14(-/-) neutrophils to respond chemotactically to MIP-2. In addition, the myeloid cell functions of phagocytosis, superoxide burst, and apoptosis were unaffected in MRP-14(-/-) cells. In an in vivo model of peritonitis, MRP-14(-/-) mice showed no difference from wild-type mice in induced inflammatory response. The data indicate that MRP-14 and MRP-8 are dispensable for many myeloid cell functions.     

Neutrophilic cell-free exudate induces antinociception mediate by the protein S100A9

Calcium-binding protein S100A9 (MRP-14) induces antinociceptive effect in an experimental model of painful sensibility and participates of antinociception observed during neutrophilic peritonitis induced by glycogen or carrageenan in mice. In this study, the direct antinociceptive role of the protein S100A9 in neutrophilic cell-free exudates obtained of mice injected with glycogen was investigated. Mice were intraperitoneally injected with a glycogen solution, and after 4, 8, 24, and 48 hours, either the pattern of cell migration of the peritoneal exudate or the nociceptive response of animals was evaluated. The glycogen-induced neutrophilic peritonitis evoked antinociception 4 and 8 hours after inoculation of the irritant. Peritoneal cell-free exudates, collected in different times after the irritant injection, were transferred to naive animals which were submitted to the nociceptive test. The transference of exudates also induced antinociceptive effect, and neutralization of S100A9 activity by anti-S100A9 monoclonal antibody totally reverted this response. This effect was not observed when experiments were made 24 or 48 hours after glycogen injection. These results clearly indicate that S100A9 is secreted during glycogen-induced neutrophilic peritonitis, and that this protein is responsible by antinociception observed in the initial phase of inflammatory reaction. Thus, these data reinforce the hypothesis that the calcium-binding protein S100A9 participates of the endogenous control of inflammatory pain.     

Distribution of the calcium-binding protein SPARC in tissues of embryonic and adult mice

SPARC (Secreted Protein that is Acidic and Rich in Cysteine), a Ca++-binding glycoprotein also known as osteonectin, is produced in significant amounts by injured or proliferating cells in vitro. To elucidate the possible function of SPARC in growth and remodeling, we examined its distribution in embryonic and adult murine tissues. Immunohistochemistry on adult mouse tissues revealed a preferential association of SPARC protein with epithelia exhibiting high rates of turnover (gut, skin, and glandular tissue). Fetal tissues containing high levels of SPARC included heart, thymus, lung, and gut. In the 14-18-day developing fetus, SPARC expression was particularly enhanced in areas undergoing chondrogenesis, osteogenesis, and somitogenesis, whereas 10-day embryos exhibited selective staining for this protein in Reichert's membrane, maternal sinuses, and trophoblastic giant cells. SPARC displayed a Ca++-dependent affinity for hydrophobic surfaces and was not incorporated into the extracellular matrix produced by cells in vitro. We propose that in some tissues SPARC associates with cell surfaces to facilitate proliferation during embryonic morphogenesis and normal cell turnover in the adult.     

Translocation of a small cytosolic calcium-binding protein (MRP-8) to plasma membrane correlates with human neutrophil activation.

To further understand the mechanisms involved in phagocyte activation in general and in NADPH oxidase activation in particular, a polyclonal antibody was raised in rabbit against a partially purified oxidase preparation. The enzyme was solubilized from zymosan-activated human neutrophils and resting cells and separated by preparative isoelectric focusing electrophoresis. A polyclonal antibody was raised in rabbit against the pI 5.0 fraction, which had the maximum superoxide-producing capacity. Analysis of the polyclonal antibody revealed marked differences between activated and resting neutrophils. The antibody recognized in particular an 8-kDa protein (p8) in resting human neutrophil cytosol and in the membrane of zymosan-activated cells. A polyclonal antibody (anti-p8) was raised against the pure cytosolic p8 protein. This anti-p8 reacted not only with p8, but also with cytosolic proteins of 14 kDa and 6 kDa. N-terminal amino acid sequence analysis of p8 revealed homology with the calcium-binding myeloid related protein (MRP-8). Upon neutrophil activation, translocation of the 8- and 14-kDa proteins to the membrane was observed with stimuli known to depend on extracellular calcium. In calcium-depleted medium, the absence of translocation correlated with a depression of superoxide production, supporting a role for the calcium-binding protein in cellular activation.     

Inhibition of human papillomavirus type 16 E7 phosphorylation by the S100 MRP-8/14 protein complex

The human papillomavirus type 16 (HPV16) E7 is a major viral oncoprotein that is phosphorylated by casein kinase II (CKII). Two S100 family calcium-binding proteins, macrophage inhibitory-related factor protein 8 (MRP-8) and MRP-14, form a protein complex, MRP-8/14, that inactivates CKII. The MRP-8/14 protein complex may inhibit CKII-mediated E7 phosphorylation and therefore may alter its interaction with cellular ligands and reduce E7 oncogenic activity. We examined the inhibitory effect of the MRP-8/14 complex on CKII activity and HPV16 E7 phosphorylation. We have shown that CKII activity and HPV16 E7 phosphorylation were inhibited by uptake of exogenous MRP-8/14 and activation of endogenous MRP-8/14. MRP-8/14-mediated inhibition of E7 phosphorylation occurred at the G1 phase of the cell cycle. Analysis of MRP expression in primary keratinocytes and in HPV16- and 18-transformed cervical and foreskin epithelial cell lines showed that expression of MRP-8, MRP-14, and the MRP-8/14 complex was detected only in primary untransformed keratinocytes and not in the HPV-infected immortalized epithelial cells. CKII activity in HPV-immortalized keratinocytes was approximately fourfold higher than in HPV-negative primary keratinocytes. Treatment of HPV-positive immortalized epithelial cells with exogenous MRP-8/14 resulted in E7 hypophosphorylation and complete inhibition of cell growth within 2 weeks, compared with HPV-negative primary and immortalized HPV-negative cervical epithelial cells, which showed 25 and 40% growth inhibition, respectively. Together these results suggests that the MRP-8/14 protein complex in HPV-infected epithelial cells may play an important role in regulation of CKII-mediated E7 phosphorylation and inhibition of its oncogenic activity.     

Increased susceptibility to isoproterenol-induced cardiac hypertrophy and impaired weight gain in mice lacking the histidine-rich calcium-binding protein

The sarcoplasmic reticulum (SR) plays a critical role in excitation-contraction coupling by regulating the cytoplasmic calcium concentration of striated muscle. The histidine-rich calcium-binding protein (HRCBP) is expressed in the junctional SR, the site of calcium release from the SR. HRCBP is expressed exclusively in muscle tissues and binds calcium with low affinity and high capacity. In addition, HRCBP interacts with triadin, a protein associated with the ryanodine receptor and thought to be involved in calcium release. Its calcium binding properties, localization to the SR, and interaction with triadin suggest that HRCBP is involved in calcium handling by the SR. To determine the function of HRCBP in vivo, we inactivated HRC, the gene encoding HRCBP, in mice. HRC knockout mice exhibited impaired weight gain beginning at 11 months of age, which was marked by reduced skeletal muscle and fat mass, and triadin protein expression was upregulated in the heart of HRC knockout mice. In addition, HRC null mice displayed a significantly exaggerated response to the induction of cardiac hypertrophy by isoproterenol compared to their wild-type littermates. The exaggerated response of HRC knockout mice to the induction of cardiac hypertrophy is consistent with a regulatory role for HRCBP in calcium handling in vivo and suggests that mutations in HRC, in combination with other genetic or environmental factors, might contribute to pathological hypertrophy and heart failure.     

The crystal structure of plant-specific calcium-binding protein AtCBL2 in complex with the regulatory domain of AtCIPK14

Calcium signals mediate a multitude of plant responses to external stimuli. Calcineurin B-like (CBL) proteins and their target kinases, CBL-interacting protein kinases (CIPKs), represent important relays in plant calcium signaling. CBL interacts with CIPK through a conserved motif (NAF/FISL motif) within the C-terminal regulatory domain. To better understand the functional role of the CBL-CIPK system, we determined the crystal structure of AtCBL2 in complex with the regulatory domain of AtCIPK14 at 1.2 Å resolution. The NAF/FISL motif is inserted into a hydrophobic crevice within AtCBL2, accompanied by a large displacement of the helices and loop on the opposite side of the NAF/FISL motif from the C-terminal region, which shields the hydrophobic crevice in free form. Ca²⁺ are coordinated within four EF hands in AtCBL2 in bound form. This calcium coordination pattern differs from that in the structure of the SOS3-SOS2 complex previously reported. Structural comparison of the two structures shows that the recognition of CBL by CIPK is performed in a similar manner, but inherent interactions confer binding affinity and specificity.     

Calcium-regulated GTPase activity in the calcium-binding protein calexcitin

Calexcitin (CE) is a calcium-binding protein, closely related to sarcoplasmic calcium-binding proteins, that is involved in invertebrate learning and memory. Early reports indicated that both Hermissenda and squid CE also could bind GTP; however, the biochemical significance of GTP-binding and its relationship to calcium binding have remained unclear. Here, we report that the GTPase activity of CE is strongly regulated by calcium. CE possessed a P-loop-like structure near the C-terminal similar to the phosphate-binding regions in other GTP-binding proteins. Site-directed mutagenesis of this region showed that Gly¹⁸², Phe¹⁸⁶ and Gly¹⁸⁷ are required for maximum affinity, suggesting that the GTP-binding motif is G-N-x-x-[FM]-G. CE cloned from Drosophila CNS possessed a similar C-terminal sequence and also bound and hydrolyzed GTP. GTPase activity in Drosophila CE was also strongly regulated by Ca²⁺, exhibiting over 23-fold higher activity in the presence of 0.3 μM calcium. Analysis of the conserved protein motifs defines a new family of Ca²⁺-binding proteins representing the first example of proteins endowed with both EF-hand calcium binding domains and a C-terminal, P-loop-like GTP-binding motif. These results establish that, in the absence of calcium, both squid and Drosophila CE bind GTP at near-physiological concentrations and hydrolyze GTP at rates comparable to unactivated ras. Calcium functions to increase GTP-binding and GTPase activity in CE, similar to the effect of GTPase activating proteins in other low-MW GTP-binding proteins. CE may, therefore, act as a molecular interface between Ca²⁺ cytosolic oscillations and the G protein-coupled signal transduction.     

Enhancement of fentanyl antinociception by subeffective doses of nitroparacetamol (NCX-701) in acute nociception and in carrageenan-induced monoarthritis

We have reported that subanalgesic doses of new generation non-steroidal anti-inflammatory drugs (NSAIDs) enhance the antinociceptive activity of the mu-opiate fentanyl, and the duration of its effect, in acute nociception. Since this therapy is intended for situations of hyperalgesia, we have compared the antinociceptive activity of fentanyl in the absence and in the presence of subeffective doses of NCX-701 (nitroparacetamol) in normal animals and in animals with carrageenan-induced monoarthritis. Subanalgesic dose of NCX-701 did not modify any of the nociceptive responses on its own but reduced the ID50 of fentanyl more than two-fold in both the normal and sensitized states. When administered alone, full recovery from fentanyl was always observed within 15 to 20 minutes, however, full recovery was not observed in the presence of NCX-701. Naloxone was unable to reverse the effect, suggesting a possible reduction of other opiate-mediated secondary effects. We therefore studied the possibility that combining administration of fentanyl and nitroparacetamol (NCX-701) would reduce the development of acute tolerance to fentanyl in behavioral experiments. Acute tolerance to fentanyl in behavioral nociceptive reflexes was developed within 72 h after the constant infusion of the drug, whereas in animals treated with small doses of NCX-701 tolerance was not observed. In summary, our results, both in normal animals and in animals with hyperalgesia, show that fentanyl antinociception can be strongly potentiated with subanalgesic doses of the NSAID NCX-701 and that the development of acute tolerance to fentanyl in normal animals is prevented by this combination of drugs.     

Vitamin D, calcium-binding protein and calcium absorption in the intestines

The author presents his own and literature data concerning the action of vitamin D and its analogs on the biosynthesis of calcium-binding protein (CaBP) in the chick intestinal mucosa. The mechanism of involvement of this protein in calcium transport across the intestinal epithelium is discussed. CaCP is considered as a specific test-substance for vitamin D. A close correlation between the CaCP content in the intestinal mucosa and the vitamin antirachitic effect is demonstrated. The quantitative estimates of the biological activity of various forms of vitamin D, their metabolites and synthetic analogs with respect to the CaCP content are given.     

Central administration of neuronostatin induces antinociception in mice

Neuronostatin, a recently discovered endogenous bioactive peptide, was encoded by pro-mRNA of somatostatin that contributes to modulation of nociception. However, nociceptive effect of neuronostatin is still not fully known. The aim of this study was to evaluate effect of neuronostatin on nociception and elucidate its possible mechanism of action. Intracerebroventricular (i.c.v.) administration of neuronostatin (0.3, 3, 6, 12 nmol/mouse) produced a dose- and time-related antinociceptive effect in the tail immersion assay in mice, an acute pain model. The antinociceptive effect of neuronostatin was significantly antagonized by naloxone, and was strongly inhibited by co-injection with β-funaltrexamine or nor-binaltorphimine, but not by naltrindole. Also, melanocortin 3/4 receptor antagonist, SHU9119, completely blocked the effect of neuronostatin. These data indicated the involvement of both μ- and κ-opioid receptors and central melanocortin system in the analgesic response induced by neuronostatin. In addition, neuronostatin (6 nmol, i.c.v.) increased c-Fos protein expression in the periaqueductal gray (PAG) and the nucleus raphe magnus (NRM) that have a pivotal role in regulating descending pain pathways. Taken together, this study is the first to reveal that neuronostatin produces antinociceptive effect via opioid and central melanocortin systems, which is associated with an increase in neuronal activity the PAG and NRM.     

Observations on the binding of lanthanides and calcium to vitamin D-dependent chick intestinal calcium-binding protein. Implications regarding calcium-binding protein function

The binding of calcium and terbium to purified chick vitamin D-dependent intestinal calcium-binding protein was studied by terbium fluorescence, circular dichroism, and intrinsic protein fluorescence techniques. Calcium-binding protein bound, with high affinity, at least 3 mol of terbium/mol of protein; numerous low affinity terbium-binding sites were also noted. The three highest affinity sites were resolved into one very high affinity site (site A) and two other sites (sites B and C) with slightly lower affinity. Resonance energy transfer from tryptophan residues to terbium occurred only with site A. This site was filled before sites B and C. Competition experiments in which calcium was used to displace terbium bound to the protein showed that larger amounts of calcium were needed to displace terbium from site A than from sites B and C. Energy transfer from terbium to holmium indicated that the terbium-binding sites (B and C) were located close to each other (about 7-12 A) but were distant (greater than 12 A) from site A. The addition of EDTA to calcium-binding protein resulted in a 25% decrease in intrinsic protein fluorescence, suggesting a conformational change in the protein. The titration of EDTA-treated calcium-binding protein with calcium resulted in recovery of intrinsic protein fluorescence. A reversible calcium-dependent change in the ellipticity of calcium-binding protein in circular dichroism experiments was also seen. These observed properties suggest that vitamin D-dependent chick intestinal calcium-binding protein behaves in a manner similar to other well-known calcium-binding regulatory proteins.