Fluid-phase interaction of C1 inhibitor (C1 Inh) and the subcomponents C1r and C1s of the first component of complement, C1.

Interactions between proenzymic or activated complement subcomponents of C1 and C1 Inh (C1 inhibitor) were analysed by sucrose-density-gradient ultracentrifugation and sodium dodecyl sulphate/polyacrylamide-gel electrophoresis. The interaction of C1 Inh with dimeric C1r in the presence of EDTA resulted into two bimolecular complexes accounting for a disruption of C1r. The interaction of C1 Inh with the Ca2+-dependent C1r2-C1s2 complex (8.8 S) led to an 8.5 S inhibited C1r-C1s-C1 Inh complex (1:1:2), indicating a disruption of C1r2 and of C1s2 on C1 Inh binding. The 8.5 S inhibited complex was stable in the presence of EDTA; it was also formed from a mixture of C1r, C1s and C1 Inh in the presence of EDTA or from bimolecular complexes of C1r-C1 Inh and C1s-C1 Inh. C1r II, a modified C1r molecule, deprived of a Ca2+-binding site after autoproteolysis, did not lead to an inhibited tetrameric complex on incubation with C1s and C1 Inh. These findings suggest that, when C1 Inh binds to C1r2-C1s2 complex, the intermonomer links inside C1r2 or C1s2 are weakened, whereas the non-covalent Ca2+-independent interaction between C1r2 and C1s2 is strengthened. The nature of the proteinase-C1 Inh link was investigated. Hydroxylamine (1M) was able to dissociate the complexes partially (pH 7.5) or totally (pH 9.0) when the incubation was performed in denaturing conditions. An ester link between a serine residue at the active site of C1r or C1s and C1 Inh is postulated.     

Presenilin dependence of phospholipase C and protein kinase C signaling

Presenilins (PSs) are involved in processing several proteins such as the amyloid precursor protein (APP), as well as in pathways for cell death and survival. We previously showed that some familial Alzheimer's disease PS mutations cause increased basal and acetylcholine muscarinic receptor-stimulated phospholipase C (PLC) activity which was gamma-secretase dependent. To further evaluate the dependence of PLC on PSs we measured PLC activity and the activation of variant protein kinase C (PKC) isoforms in mouse embryonic fibroblasts (MEFs) lacking either PS1, PS2, or both. PLC activity and PKCalpha and PKCgamma activations were significantly lower in PS1 and PS2 double knockout MEFs after PLC stimulation. Protein levels of PKCalpha and PKCgamma were lower in PS1 and PS2 double knockout MEFs. In contrast, PKCdelta levels were significantly elevated in PS1 and PS2 double knockout as well as in PS1 knockout MEFs. Also, PKCdelta levels were lowered after transfection of PS1 into PS1 knockout or PS double knockout MEFs. Using APP knockout MEFs we showed that the expression of PKCalpha, but not the other PKC isoforms is partially dependent on APP and can be regulated by APP intracellular domain (AICD). These results show that PLC and PKC activations are modulated by PS and also that PSs differentially regulate the expression of PKC isoforms by both APP/AICD-dependent and independent mechanisms.     

Sphingosine 1-phosphate inhibits cell migration in C2C12 myoblasts

This study shows that sphingosine 1-phosphate (S1P) exerts an anti-migratory action in C2C12 myoblasts by reducing directional cell motility and fully abrogating the chemotactic response to insulin-like growth factor-1. The anti-migratory response to S1P required ligation to S1P(2), being attenuated in myoblasts where the receptor was down-regulated by specific antisense oligodeoxyribonucleotides or small interfering RNA (siRNA) and conversely potentiated in S1P(2)-overexpressing myoblasts. The investigation of RhoA and Rac GTPases, critically implicated in cell motility regulation, demonstrated that RhoA was rapidly activated by S1P, while Rac1 was unaffected within the first 5 min but stimulated thereafter. RhoA, but not Rac activation, was identified as a S1P(2)-dependent pathway in experiments in which receptor expression was attenuated by siRNA treatment or up-regulated by S1P(2)-encoding plasmid transfection. Finally, by expression of the dominant negative mutant of RhoA, the GTPase was found implicated in the anti-migratory action of S1P, whereas modulation of Rac1 functionality unaffected the anti-chemotactic effect of S1P, ruling out a role for this protein in the biological response. Since S1P was previously shown to inhibit myoblast proliferation and stimulate myogenesis, the here identified novel biological activity is in favour of a complex physiological role of the sphingolipid in the process of muscle repair.     

RAGE binds C1q and enhances C1q-mediated phagocytosis

RAGE, the multiligand receptor of the immunoglobulin superfamily of cell surface molecules, is implicated in innate and adaptive immunity. Complement component C1q serves roles in complement activation and antibody-independent opsonization. Using soluble forms of RAGE (sRAGE) and RAGE-expressing cells, we determined that RAGE is a native C1q globular domain receptor. Direct C1q-sRAGE interaction was demonstrated with surface plasmon resonance (SPR), with minimum K(d) 5.6 μM, and stronger binding affinity seen in ELISA-like experiments involving multivalent binding. Pull-down experiments suggested formation of a receptor complex of RAGE and Mac-1 to further enhance affinity for C1q. C1q induced U937 cell adhesion and phagocytosis was inhibited by antibodies to RAGE or Mac-1. These data link C1q and RAGE to the recruitment of leukocytes and phagocytosis of C1q-coated material.     

Arabidopsis CYP90B1 catalyses the early C-22 hydroxylation of C27, C28 and C29 sterols

Arabidopsis dwf4 is a brassinosteroid (BR)-deficient mutant, and the DWF4 gene encodes a cytochrome P450, CYP90B1. We report the catalytic activity and substrate specificity of CYP90B1. Recombinant CYP90B1 was produced in Escherichia coli, and CYP90B1 activity was measured in an in vitro assay reconstituted with NADPH-cytochrome P450 reductase. CYP90B1 converted campestanol (CN) to 6-deoxocathasterone, confirming that CYP90B1 is a steroid C-22 hydroxylase. The substrate specificity of CYP90B1 indicated that sterols with a double bond at positions C-5 and C-6 are preferred substrates compared with stanols, which have no double bond at the position. In particular, the catalytic efficiency (k(cat)/K(m)) of CYP90B1 for campesterol (CR) was 325 times greater than that for CN. As CR is more abundant than CN in planta, the results suggest that C-22 hydroxylation of CR before C-5alpha reduction is the main route of BR biosynthetic pathway, which contrasts with the generally accepted route via CN. In addition, CYP90B1 showed C-22 hydroxylation activity toward various C(27-29) sterols. Cholesterol (C27 sterol) is the best substrate, followed by CR (C28 sterol), whereas sitosterol (C29 sterol) is a poor substrate, suggesting that the substrate preference of CYP90B1 may explain the discrepancy between the in planta abundance of C27/C28/C29 sterols and C27/C28/C29 BRs.     

C1 dissociation. Spontaneous generation in human serum of a trimer complex containing C1 inactivator, activated C1r, and zymogen C1s

Activation of the C1 complex in the presence of C1 inactivator (C1 IA) is known to result in the formation of tetramer C1 IA-C1r-C1s-C1 IA complexes that are dissociated from C1q. Both C1r and C1s of the tetramers are present in their activated forms. The present investigation concerned the generation of trimer complexes containing C1 IA, activated C1r, and zymogen C1s (C1 IA-C1r-C1s). C1 IA-C1r-C1s were released from C1q and were formed in high concentration during prolonged incubation (1 to 3 days) of normal serum at 37 degrees C without addition of activators. By contrast, dissociation of C1 with formation of C1 IA-C1r-C1s-C1 IA was complete within 30 min at 37 degrees C, when the serum was treated with heat-aggregated IgG (1 g/liter). On size exclusion chromatography (TSK-4000), C1 IA-C1r-C1s and C1 IA-C1r-C1s-C1 IA emerged with apparent m.w. of 320,000 and 460,000, respectively. The composition of the complexes was examined by absorption of serum with F(ab')2 anti-C1s- or anti-C1r-coated Sepharose beads. Eluates were analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis combined with immunoblotting. Under nonreducing conditions, heat-aggregated IgG-treated serum showed high concentrations of C1 IA-C1r (m.w. 202,000) and C1 IA-C1s (m.w. 194,000), while serum incubated at 37 degrees C without activators showed high concentrations of C1 IA-C1r but no C1 IA-C1s. Under reducing conditions, heat-aggregated IgG-treated serum showed m.w. 120,000 and 110,000 complexes of C1 IA and the C1r and C1s light chains, respectively. Uncleaved C1s and the m.w. 120,000 complex was found in serum that was incubated at 37 degrees C without activators. Consistent with results obtained by size exclusion chromatography, analysis by crossed immunoelectrophoresis and by electroimmunoassay showed that C1s could be released from C1 IA-C1r-C1s in the presence of EDTA.     

Activator-bound C1 is less susceptible to inactivation by C1 inhibition than is fluid-phase C1

Parameters that influence the effective interaction of C1 with the serum regulatory glycoprotein C1 Inhibitor were investigated. C1 that bound to activator particles EAC4 or EA was strikingly less susceptible to inactivation by C1 Inhibitor than was fluid-phase C1. By using the conventional hemolytic assay, the concentrations of C1 Inhibitor required for inhibition of C1 bound to EAC4 were 1000-fold higher than those required for fluid-phase C1. With EA as the activator (and indicator) particle, 17- to 75-fold higher concentrations of C1 Inhibitor were required to inhibit bound vs free C1. These findings suggest that, on binding to these particulate immune complexes, the domain of the C1 molecule capable of interacting with C1 Inhibitor is less available for binding than when C1 is in fluid phase. Alternatively, the conformation of C1 may be altered when bound to EA or EAC4, resulting in a lower association constant of C1 Inhibitor for C1. As assessed by inhibition of classical complement pathway hemolysis, the inhibition of the enzymatic activity of C1 by C1 Inhibitor (both in the fluid phase and particle-bound) was markedly dependent on the concentration of the reactants. Incubation of C1 and C1 Inhibitor at serum concentrations resulted in the inhibition of more than 10 times the amount of C1 hemolytic activity than that which occurred when the same ratio of components was incubated at the more dilute concentrations used in the conventional hemolytic assays. These findings have allowed for the development of a more sensitive and rapid assay for C1 Inhibitor function.     

Ceramide 1-phosphate stimulates proliferation of C2C12 myoblasts

Recent studies have established specific cellular functions for different bioactive sphingolipids in skeletal muscle cells. Ceramide 1-phosphate (C1P) is an important bioactive sphingolipid that has been involved in cell growth and survival. However its possible role in the regulation of muscle cell homeostasis has not been so far investigated. In this study, we show that C1P stimulates myoblast proliferation, as determined by measuring the incorporation of tritiated thymidine into DNA, and progression of the myoblasts through the cell cycle. C1P induced phosphorylation of glycogen synthase kinase-3β and the product of retinoblastoma gene, and enhanced cyclin D1 protein levels. The mitogenic action of C1P also involved activation of phosphatidylinositol 3-kinase/Akt, ERK1/2 and the mammalian target of rapamycin. These effects of C1P were independent of interaction with a putative G(i)-coupled C1P receptor as pertussis toxin, which maintains G(i) protein in the inactive form, did not affect C1P-stimulated myoblast proliferation. By contrast, C1P was unable to inhibit serum starvation- or staurosporine-induced apoptosis in the myoblasts, and did not affect myogenic differentiation. Collectively, these results add up to the current knowledge on cell types targeted by C1P, which so far has been mainly confined to fibroblasts and macrophages, and extend on the mechanisms by which C1P exerts its mitogenic effects. Moreover, the biological activities of C1P described in this report establish that this phosphosphingolipid may be a relevant cue in the regulation of skeletal muscle regeneration, and that C1P-metabolizing enzymes might be important targets for developing cellular therapies for treatment of skeletal muscle degenerative diseases, or tissue injury.     

Stretch activation of GTP-binding proteins in C2C12 myoblasts

Mechanical stimulation has been proposed as a fundamental determinant of muscle physiology. The mechanotransduction of strain and strain rate in C2C12 myoblasts were investigated utilizing a radiolabeled GTP analogue to detect stretch-induced GTP-binding protein activation. Cyclic uniaxial strains of 10% and 20% at a strain rate of 20% s(-1) rapidly (within 1 min) activated a 25-kDa GTPase (183 +/- 17% and 186 +/- 19%, respectively), while 2% strain failed to elicit a response (109 +/- 11%) relative to controls. One, five, and sixty cycles of 10% strain elicited 187 +/- 20%, 183 +/- 17%, and 276 +/- 38% increases in activation. A single 10% stretch at 20% s(-1), but not 0.3% s(-1), resulted in activation. Insulin activated the same 25-kDa band in a dose-dependent manner. Western blot analysis revealed a panel of GTP-binding proteins in C2C12 myoblasts, and tentatively identified the 25-kDa GTPase as rab5. In separate experiments, a 40-kDa protein tentatively identified as Galpha(i) was activated (240 +/- 16%) by 10% strain at 1 Hz for 15 min. These results demonstrate the rapid activation of GTP-binding proteins by mechanical strain in myoblasts in both a strain magnitude- and strain rate-dependent manner.     

Complement C2 receptor inhibitor trispanning and the beta-chain of C4 share a binding site for complement C2

Complement C2 receptor inhibitor trispanning (CRIT) of the Schistosoma parasite binds human C2 via the C2a segment. The receptor in vivo functions as C2 decoy receptor by directly competing with C4b for binding to C2. As a result, CRIT is able to limit the extent of classical pathway (CP) C3 convertase formation. We report that the CRIT-extracellular domain 1 (ed1) peptide inhibits CP-mediated complement activation with an ICH(50) of approximately 0.1 microM, the C-terminal 11 aa of CRIT-ed1, named H17, even more effectively. The beta-chain region F222-Y232 of C4 shares 55% identity and 73% similarity with H17. Peptides based on this region also inhibit CP in a dose-dependent manner. As further evidence of C2 binding we showed CRIT-ed1 peptides and homologous C4 beta-chain peptides to inhibit complement in C2 hemolytic assays. We have predicted C4 beta-c F222-Y232 as a C2 binding site which we have termed the CRIT-ed1 domain, and the sequence [F/H]EVKX(4/5)P as a consensus C2-binding sequence. Anti-CRIT-ed1 cross-reacts with the C4 beta-chain and F222EVKITPGKPY232 appears to be the key epitope recognized by this Ab. Furthermore, anti-CRIT-ed1 was found to inhibit CP activation in a total hemolytic assay. We believe that Schistosoma CRIT-ed1, as well as C4 beta-chain peptides based on the CRIT-ed1 domain, function as interface peptides. These peptides, based on C2-binding sequences in CRIT, or C4, competitively inhibit the binding of C2 to C4b and thus limit the activation of C. The C4 peptides, unlike CRIT-ed1, did not inhibit the cleavage of C2 by C1s.     

Control of C1 activation by nascent C3b and C4b: a mechanism of feedback inhibition

We have demonstrated that immune complexes turn over C1, i.e., limiting quantities of immune complexes activate an excess of C1. This was readily apparent in a system of purified C1 and C1-inhibitor (C1-In) but not in normal human serum (NHS). The following results indicate that C3 and C4 are the serum factors responsible for the inhibition of C1 turnover by immune complexes. 1) In a purified protein system composed of C1 and C1-In at pH 7.5, ionic strength 0.14 M, doses of immune complexes that activated all the C1 in 60 min at 37 degrees C yielded no detectable C1 activation when C2, C3, and C4 were also present. All proteins were at their physiologic concentrations. Activation was quantified by SDS-PAGE analysis and hemolytic titration 2) In order to inactivate C3 and C4, NHS was treated with 50 mM methylamine (MeAm) for 15 min at 37 degrees C, after which the MeAm was removed by dialysis. The activities of C1, C2, and C1-In were unaffected by this treatment. Doses of immune complexes that consumed no C1 in NHS, consumed all the C1 in MeAm-treated NHS (MeAm-NHS). 3) Reconstitution of MeAm-NHS with physiologic concentrations of C3 and C4 rendered the serum again resistant to excessive C1 consumption by immune complexes. Immune complexes used in these studies included EA-IgG, EA-IgM, tetanus-human anti-tetanus, and aggregated human IgG. There appeared to be specificity to the inhibition reaction since C4 by itself could inhibit C1 consumption by EA-IgM, whereas the presence of C3 was also required to control EA-IgG. Finally, N-acetyl-L-tyrosine was added to NHS at a final concentration of 30 mM. This nucleophile did not interact with native C3 or C4, nor did it directly activate C1. However, upon the addition of low doses of immune complexes, acetyl tyrosine did yield uncontrolled C1 activation, presumably by binding nascent C3b and C4b and thereby blocking their attachment to the immune complexes. We conclude that in NHS there is a mechanism of feedback inhibition by which nascent C3b and C4b inhibit C1 turnover by immune complexes. This mechanism of control might be physiologically important in that it prevents excessive complement activation by low concentrations of immune complexes.     

The glycolipids of Lactobacillus casei A.T.C.C. 7469

1. The lipids were extracted from Lactobacillus casei A.T.C.C. 7469 with chloroform-methanol mixtures. The glycolipids were obtained by chromatography on silicic acid and DEAE-cellulose (acetate form). 2. Hydrolysis of the glycolipids with alkali gave two glycerol glycosides and a mixture of fatty acids. 3. The glycosides were separated and their structures elucidated. The major component was O-alpha-d-galactopyranosyl-(1-->2)-O-alpha-d-glucopyranosyl-(1-->1)-glycerol and the minor component O-alpha-d-glucopyranosyl-(1-->6)-O-alpha-d-galactopyranosyl-(1-->2)-O-alpha-d-glucopyranosyl-(1-->1)-glycerol. 4. Analysis of the fatty acids by gas-liquid chromatography showed that they were predominantly palmitic acid, octadecenoic acid and lactobacillic acid.     

Structure and activity of C1r and C1s

During activation of the first component of the classical complement pathway the two zymogen subcomponents, C1r and C1s are converted to active proteolytic enzymes. Activated C1r cleaves C1s which then becomes the activator of C4 and C2. Amino acid sequence studies of the proteolytic chains of C1r and C1s, carried out in Oxford and Aberdeen respectively, have shown that they belong to the serine proteinase family. Modelling of these sequences to the three-dimensional coordinates of chymotrypsin (Birktoft & Blow 1972) reveals that both molecules have a conserved structural core, and that most of the differences lie in the external loops. Catalytically functional residues (Ile-16, His-57, Asp-102, Ser-195) are conserved, and residue 189 is aspartic acid, consistent with the known trypsin-like specificity of cleavage. Examination of the amino acid sequences of C4a, and comparison with those of the homologous molecules C3a and C5a, shows that there is a marked difference in the distribution of basic residues near the C-terminal arginine residue which is the site of action of C1s. When these amino acid sequences are modelled to the coordinates of C3a (Huber et al. 1980) and docked to the active site of C1s, the basic residues of C4a appear to interact with two glutamate residues peculiar to C1s, suggesting that this interaction may contribute to the ability of C1s to discriminate C4 from C3 and C5.     

Interaction of two prolamins with 1-13C oleic acid by 13C NMR

In this paper, we analyzed the interaction of Z19 prolamin from a BR451 maize variety and pennisetin from a BRS1501 pearl millet variety with 1-(13)C-enriched oleic acid (OA) by (13)C NMR in solution. In both proteins, we identified the presence of free fatty acids by NMR in solid state and solution. The interactions were analyzed at the protein/OA molar ratios of 1:1 and 1:4. In the Z19/OA 1:1 mixture in 70% ethanol and 30% D(2)O, the chemical shift of OA C1 was 182.9 ppm, about 3 ppm above that of the pure OA in the same solvent. In contrast, upon addition of OA to the pennisetin (1:1), the chemical-shift value slightly decreased by less than 1 ppm. The chemical-shift titration curve of OA C1 in an apparent pH range of 5.5-7.3 shifted by approximately 0.3 pH units toward higher pH values in the pennisetin/OA 1:1 complex relative to the pure OA. The results obtained for the pennisetin/OA 1:4 mixture were similar to the complexes at a 1:1 molar ratio. A significant difference was observed between the 1:1 and 1:4 curves for Z19. The titration curve for Z19/OA 1:1 suggested specific binding at the sites with electrostatic interaction.     

Demonstration of the interaction of native C1 with monomeric immunoglobulins and C1 inhibitor

The association of native C1 with physiologically relevant proteins was studied by ultracentrifugation. 125I-C1 was centrifuged through numerous sucrose density gradients, each of which contained a different concentration of monomeric (19S) IgM throughout the gradient. The s-rate of C1 (16S) increased with increasing IgM input to a maximum of 32S. In the absence of C1q, the C1r2s2 subunit did not bind to the Ig. In gradients containing physiologic concentrations of IgM (1.3 mg/ml) at 0.14 M ionic strength, the observed s-rate of C1 was 21S. In the presence of 13 mg/ml IgG, C1 sedimented with an s-rate of 19S. Thus, under physiologic conditions, a significant fraction of native C1 is reversibly bound to monomeric Ig. SDS-PAGE analyses show that this interaction does not lead to C1 activation. The interaction of native C1 with C1 inhibitor (C1-In) was studied by ultracentrifugation at physiologic ionic strength. Purified 125I-C1-In alone sedimented with an s-rate of 4S. However in the presence of excess native C1, one-third of the C1-In co-sedimented with C1 at a 16S position. For these studies, 100 microM nitrophenylguanidinobenzoate (NPGB) was present throughout the sucrose density gradient to prevent C1 activation during centrifugation. As the concentration of NPGB was increased, the percent of 125I-C1-In at 16S decreased, indicating that C1-In was binding (reversibly) to the C1 active site region(s), which is at least partially accessible in uncleaved C1. In controls, when NPGB was omitted or activated C1 was used, the s-rate of 125I-C1-In was only 12S due to the release of C1rC1s(C1-In)2 from activated C1. Thus, under physiologic conditions native C1 is reversibly bound to C1-In.     

Importance of C1B domain for lipid messenger-induced targeting of protein kinase C

The molecular mechanisms by which arachidonic acid (AA) and ceramide elicit translocation of protein kinase C (PKC) were investigated. Ceramide translocated epsilonPKC from the cytoplasm to the Golgi complex, but with a mechanism distinct from that utilized by AA. Using fluorescence recovery after photobleaching, we showed that, upon treatment with AA, epsilonPKC was tightly associated with the Golgi complex; ceramide elicited an accumulation of epsilonPKC which was exchangeable with the cytoplasm. Stimulation with ceramide after AA converted the AA-induced Golgi complex staining to one elicited by ceramide alone; AA had no effect on the ceramide-stimulated localization. Using point mutants and deletions of epsilonPKC, we determined that the epsilonC1B domain was responsible for the ceramide- and AA-induced translocation. Switch chimeras, containing the C1B from epsilonPKC in the context of deltaPKC (delta(epsilonC1B)) and vice versa (epsilon(deltaC1B)), were generated and tested for their translocation in response to ceramide and AA. delta(epsilonC1B) translocated upon treatment with both ceramide and AA; epsilon(deltaC1B) responded only to ceramide. Thus, through the C1B domain, AA and ceramide induce different patterns of epsilonPKC translocation and the C1B domain defines the subtype specific sensitivity of PKCs to lipid second messengers.