Human complement subcomponent C2: purification and proteolytic cleavage in fluid phase by C1s, C1r2-C1s2 and C1

Photosynthetic membranes contain considerable regions of high surface curvature, notably at their margins, where the average radius of curvature is about 10 nm. The proportion of total membrane lipid in the outer and inner thylakoid margin monolayers is estimated at 21% and 13%, respectively. The major thylakoid lipid, monogalactosyldiacylglycerol, is roughly cone-shaped and will not form complete lamellar bilayer phases, even in combination with other thylakoid lipids. It is proposed that this galactolipid plays a role in: (a) stabilising regions of concave curvature in thylakoids; and (b) packaging hydrophobic proteins in planar bilayer regions by means of inverted micelles. This model predicts substantial asymmetries in the distribution of lipids both across and along the thylakoid bilayer plane.     

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.     

Switching the Clientele: A LYSINE RESIDING IN THE C TERMINUS OF THE SEROTONIN TRANSPORTER SPECIFIES ITS PREFERENCE FOR THE COAT PROTEIN COMPLEX II COMPONENT SEC24C*

The serotonin transporter (SERT) maintains serotonergic neurotransmission via rapid reuptake of serotonin from the synaptic cleft. SERT relies exclusively on the coat protein complex II component SEC24C for endoplasmic reticulum (ER) export. The closely related transporters for noradrenaline and dopamine depend on SEC24D. Here, we show that discrimination between SEC24C and SEC24D is specified by the residue at position +2 downstream from the ER export motif (⁶⁰⁷RI⁶⁰⁸ in SERT). Substituting Lys⁶¹⁰ with tyrosine, the corresponding residue found in the noradrenaline and dopamine transporters, switched the SEC24 isoform preference: SERT-K610Y relied solely on SEC24D to reach the cell surface. This analysis was extended to other SLC6 (solute carrier 6) transporter family members: siRNA-dependent depletion of SEC24C, but not of SEC24D, reduced surface levels of the glycine transporter-1a, the betaine/GABA transporter and the GABA transporter-4. Experiments with dominant negative versions of SEC24C and SEC24D recapitulated these findings. We also verified that the presence of two ER export motifs (in concatemers of SERT and GABA transporter-1) supported recruitment of both SEC24C and SEC24D. To the best of our knowledge, this is the first report to document a change in SEC24 specificity by mutation of a single residue in the client protein. Our observations allowed for deducing a rule for SLC6 family members: a hydrophobic residue (Tyr or Val) in the +2 position specifies interaction with SEC24D, and a hydrophilic residue (Lys, Asn, or Gln) recruits SEC24C. Variations in SEC24C are linked to neuropsychiatric disorders. The present findings provide a mechanistic explanation. Variations in SEC24C may translate into distinct surface levels of neurotransmitter transporters.     

Topology and structure of the C1q-binding site on C-reactive protein

The host defense functions of human C-reactive protein (CRP) depend to a great extent on its ability to activate the classical complement pathway. The aim of this study was to define the topology and structure of the CRP site that binds C1q, the recognition protein of the classical pathway. We have previously reported that residue Asp(112) of CRP plays a major role in the formation of the C1q-binding site, while the neighboring Lys(114) hinders C1q binding. The three-dimensional structure of CRP shows the presence of a deep, extended cleft in each protomer on the face of the pentamer opposite that containing the phosphocholine-binding sites. Asp(112) is part of this marked cleft that is deep at its origin but becomes wider and shallower close to the inner edge of the protomer and the central pore of the pentamer. The shallow end of the pocket is bounded by the 112-114 loop, residues 86-92 (the inner loop), the C terminus of the protomer, and the C terminus of the pentraxin alpha-helix 169-176, particularly Tyr(175). Mutational analysis of residues participating in the formation of this pocket demonstrates that Asp(112) and Tyr(175) are important contact residues for C1q binding, that Glu(88) influences the conformational change in C1q necessary for complement activation, and that Asn(158) and His(38) probably contribute to the correct geometry of the binding site. Thus, it appears that the pocket at the open end of the cleft is the C1q-binding site of CRP.     

Identification of Novel in Vivo Phosphorylation Sites of the Human Proapoptotic Protein BAD: PORE-FORMING ACTIVITY OF BAD IS REGULATED BY PHOSPHORYLATION*

BAD is a proapoptotic member of the Bcl-2 protein family that is regulated by phosphorylation in response to survival factors. Although much attention has been devoted to the identification of phosphorylation sites in murine BAD, little data are available with respect to phosphorylation of human BAD protein. Using mass spectrometry, we identified here besides the established phosphorylation sites at serines 75, 99, and 118 several novel in vivo phosphorylation sites within human BAD (serines 25, 32/34, 97, and 124). Furthermore, we investigated the quantitative contribution of BAD targeting kinases in phosphorylating serine residues 75, 99, and 118. Our results indicate that RAF kinases represent, besides protein kinase A, PAK, and Akt/protein kinase B, in vivo BAD-phosphorylating kinases. RAF-induced phosphorylation of BAD was reduced to control levels using the RAF inhibitor BAY 43-9006. This phosphorylation was not prevented by MEK inhibitors. Consistently, expression of constitutively active RAF suppressed apoptosis induced by BAD and the inhibition of colony formation caused by BAD could be prevented by RAF. In addition, using the surface plasmon resonance technique, we analyzed the direct consequences of BAD phosphorylation by RAF with respect to association with 14-3-3 and Bcl-2/Bcl-X_L proteins. Phosphorylation of BAD by active RAF promotes 14-3-3 protein association, in which the phosphoserine 99 represented the major binding site. Finally, we show here that BAD forms channels in planar bilayer membranes in vitro. This pore-forming capacity was dependent on phosphorylation status and interaction with 14-3-3 proteins. Collectively, our findings provide new insights into the regulation of BAD function by phosphorylation.Apoptosis is a genetically programmed, morphologically distinct form of cell death that can be triggered by a variety of physiological and pathological stimuli (1–3). This form of cellular suicide is widely observed in nature and is not only essential for embryogenesis, immune responses, and tissue homeostasis but is also involved in diseases such as tumor development and progression. Bcl-2 family proteins play a pivotal role in controlling programmed cell death. The major function of these proteins is to directly modulate outer mitochondrial membrane permeability and thereby regulate the release of apoptogenic factors from the intermembrane space into the cytoplasm (for a recent review, see Ref. 4). On the basis of various structural and functional characteristics, the Bcl-2 family of proteins is divided into three subfamilies, including proteins that either inhibit (e.g. Bcl-2, Bcl-X_L, or Bcl-w) or promote programmed cell death (e.g. Bax, Bak, or Bok) (5, 6). A second subclass of proapoptotic Bcl-2 family members, the BH3²-only proteins, comprises BAD, Bik, Bmf, Hrk, Noxa, truncated Bid, Bim, and Puma (4). BH3-only proteins share sequence homology only at the BH3 domain. The amphipathic helix formed by the BH3 domain (and neighboring residues) associates with a hydrophobic groove of the antiapoptotic Bcl-2 family members (7, 8). Originally, truncated Bid has been reported to interact with Bax and Bak (9), suggesting that some BH3-only proteins promote apoptosis via at least two different mechanisms: inactivating Bcl-2-like proteins by direct binding and/or by inducing modification of Bax-like molecules. BAD (Bcl-2-associated death promoter, Bcl-2 antagonist of cell death) was described to promote apoptosis by forming heterodimers with the prosurvival proteins Bcl-2 and Bcl-X_L, thus preventing them from binding with Bax (10). More recently, two major models have been suggested for how BH3-only proteins may induce apoptosis. In the direct model, all BH3-only proteins promote cell death by directly binding and inactivating their specific anti-death Bcl-2 protein partner (11, 12). In this model, the relative killing potency of different BH3-only proteins is based on their affinities for antiapoptotic proteins. Thus, the activation of Bax/Bak would be mediated through their release from antiapoptotic counterparts. Contrary to this model, Kim et al. (13) provided support for an alternative hierarchy model, in which BH3-only proteins are divided into two distinct subsets. According to this model, the inactivator BH3-only proteins, like BAD, Noxa, and some others, respond directly to survival factors, resulting in phosphorylation, 14-3-3 binding, and suppression of the proapoptotic function. In the absence of growth factors, these proteins engage specifically their preferred antiapoptotic Bcl-2 proteins. The targeted Bcl-2 proteins then release the other subset of BH3-only proteins designated the activators (truncated Bid, Bim, and Puma) that in turn bind to and activate Bax and Bak.Non-phosphorylated BAD associated with Bcl-2/Bcl-X_L is found at the outer mitochondrial membrane. Phosphorylation of specific serine residues, Ser-112 and Ser-136 of mouse BAD (mBAD) or the corresponding phosphorylation sites Ser-75 and Ser-99 of human BAD (hBAD), results in association with 14-3-3 proteins and subsequent relocation of BAD (14, 15). Phosphorylation of mBAD at Ser-155 (Ser-118 of hBAD) within its BH3 domain disrupts the association with Bcl-2 or Bcl-X_L, promoting cell survival (16). Therefore, the phosphorylation status of BAD at these serine residues reflects a checkpoint for cell death or survival. Although the C-RAF kinase was the first reported BAD kinase (17), its target sites were not clearly defined. However, there is a growing body of evidence for direct participation of RAF in regulation of apoptosis via BAD (18, 19). In addition, Kebache et al. (20) reported recently that the interaction between adaptor protein Grb10 and C-RAF is essential for BAD-mediated cell survival. On the other hand, numerous reports suggest that PKA (21), Akt/PKB (22), PAK (18, 23, 24), Cdc2 (25), RSK (26, 27), CK2 (28), and PIM kinases (29) are involved in BAD phosphorylation as well. The involvement of c-Jun N-terminal kinase in BAD phosphorylation is controversially discussed. Whereas Donovan et al. (30) reported that c-Jun N-terminal kinase phosphorylates mBAD at serine 128, Zhang et al. (31) claimed that c-Jun N-terminal kinase is not a BAD-serine 128 kinase. On the other hand, it has been shown that c-Jun N-terminal kinase is able to suppress IL-3 withdrawal-induced apoptosis via phosphorylation of mBAD at threonine 201 (32). Thus, taken together, with respect to regulation of mBAD by phosphorylation, five serine phosphorylation sites (at positions 112, 128, 136, 155, and 170) and two threonines (117 and 201) have been identified so far. Intriguingly, only little data are available regarding the role of phosphorylation in regulation of hBAD protein, although significant structural differences between these two BAD proteins exist.During apoptosis, some members of the Bcl-2 family of proteins, such as Bax or Bak, have been shown to induce permeabilization of the outer mitochondrial membrane, allowing proteins in the mitochondrial intermembrane space to escape into the cytosol, where they can initiate caspase activation and cell death (for a review, see Refs. 33 and 34). Despite intensive investigation, the mechanism whereby Bax and Bak induce outer membrane permeability remains controversial (34). Based on crystal structure (35), it became evident that Bcl-X_L has a pronounced similarity to the translocation domain of diphtheria toxin (36), a domain that can form pores in artificial lipid bilayers. This discovery provoked the predominant view that upon commitment to apoptosis, the proapoptotic proteins Bax and Bak also form pores in the outer mitochondrial membrane (37). As expected from the structural considerations, Bcl-X_L was found to form channels in synthetic lipid membranes (38). Since then, other Bcl-2 family members like Bcl-2, Bax, and the BH3-only protein Bid have been reported to have channel-forming ability. These pores can be divided into two different types: proteinaceous channels of defined size and ion specificity (38–42) and large lipidic pores that allow free diffusion of 2-megadalton macromolecules (43, 44). With respect to the BH3-only protein BAD, no pore-forming abilities have been reported so far, although human BAD has been found to possess per se high affinity for negatively charged phospholipids and liposomes, mimicking mitochondrial membranes (14).The RAF kinases (A-, B-, and C-RAF) play a central role in the conserved Ras-RAF-MEK-ERK signaling cascade and mediate cellular responses induced by growth factors (45–47). Direct involvement of C-RAF in inhibition of proapoptotic properties of BAD established a link between signal transduction and apoptosis control (48, 49). However, the early works did not identify the exact RAF phosphorylation sites on BAD (17). Here we demonstrate that hBAD serves as a substrate of RAF isoforms. With respect to hBAD phosphorylation by PKA, Akt/PKB, and PAK1 in vivo, we observed different specificity compared with RAF kinases. hBAD phosphorylation by RAF was accompanied by reduced apoptosis in HEK293 cells (transformed human embryonic kidney cells) and NIH 3T3 cells (a mouse embryonic fibroblast cell line). Furthermore, we show that in vitro phosphorylation of hBAD by RAF at serines 75, 99, and 118 regulates the binding of 14-3-3 proteins and association with Bcl-2 and Bcl-X_L. By use of mass spectrometry, we detected several novel in vivo phosphorylation sites of hBAD in addition to the established phosphorylation sites, serines 75, 99, and 118. Finally, we show here that hBAD forms channels in planar bilayer membranes in vitro. This pore-forming capacity was dependent on phosphorylation status and interaction with 14-3-3 proteins.     

Differential Involvement of Atg16L1 in Crohn Disease and Canonical Autophagy: ANALYSIS OF THE ORGANIZATION OF THE Atg16L1 COMPLEX IN FIBROBLASTS*

A single nucleotide polymorphism in Atg16L1, an autophagy-related gene (ATG), is a risk factor for Crohn disease, a major form of chronic inflammatory bowel disease. However, it is still unknown how the Atg16L1 variant contributes to disease development. The Atg16L1 protein possesses a C-terminal WD repeat domain whose function is entirely unknown, and the Crohn disease-associated mutation (T300A) is within this domain. To elucidate the function of the WD repeat domain, we established an experimental system in which a WD repeat domain mutant of Atg16L1 is stably expressed in Atg16L1-deficient mouse embryonic fibroblasts. Using the system, we show that the Atg16L1 complex forms a dimeric complex and that the total Atg16L1 protein level is strictly maintained, possibly by the ubiquitin proteasome system. Furthermore, we show that an Atg16L1 WD repeat domain deletion and the T300A mutant have little impact on canonical autophagy and autophagy against Salmonella enterica serovar Typhimurium. Therefore, we propose that Atg16L1 T300A is differentially involved in Crohn disease and canonical autophagy.     

Mapping Surface Accessibility of the C1r/C1s Tetramer by Chemical Modification and Mass Spectrometry Provides New Insights into Assembly of the Human C1 Complex

C1, the complex that triggers the classic pathway of complement, is a 790-kDa assembly resulting from association of a recognition protein C1q with a Ca²⁺-dependent tetramer comprising two copies of the proteases C1r and C1s. Early structural investigations have shown that the extended C1s-C1r-C1r-C1s tetramer folds into a compact conformation in C1. Recent site-directed mutagenesis studies have identified the C1q-binding sites in C1r and C1s and led to a three-dimensional model of the C1 complex (Bally, I., Rossi, V., Lunardi, T., Thielens, N. M., Gaboriaud, C., and Arlaud, G. J. (2009) J. Biol. Chem. 284, 19340–19348). In this study, we have used a mass spectrometry-based strategy involving a label-free semi-quantitative analysis of protein samples to gain new structural insights into C1 assembly. Using a stable chemical modification, we have compared the accessibility of the lysine residues in the isolated tetramer and in C1. The labeling data account for 51 of the 73 lysine residues of C1r and C1s. They strongly support the hypothesis that both C1s CUB₁-EGF-CUB₂ interaction domains, which are distant in the free tetramer, associate with each other in the C1 complex. This analysis also provides the first experimental evidence that, in the proenzyme form of C1, the C1s serine protease domain is partly positioned inside the C1q cone and yields precise information about its orientation in the complex. These results provide further structural insights into the architecture of the C1 complex, allowing significant improvement of our current C1 model.     

Identification of erythro-beta-hydroxyasparagine in the EGF-like domain of human C1r

Previous studies [(1987) Biochem. J. 241, 711-720] have shown that position 150 of human C1r is occupied by a modified amino acid that, after acid hydrolysis, yields erythro-beta-hydroxyaspartic acid. In view of further investigations on the nature of this residue, peptide CN1a T8/T9 TL8 (positions 147-155) was isolated from C1r A chain by CNBr cleavage followed by enzymatic cleavages by trypsin and thermolysin. Amino acid analysis, sequential Edman degradation and FAB-MS of this peptide indicate that the residue at position 150 is an erythro-beta-hydroxyasparagine resulting from post-translational hydroxylation of asparagine.     

Trp2313-His2315 of Factor VIII C2 Domain Is Involved in Membrane Binding: STRUCTURE OF A COMPLEX BETWEEN THE C2 DOMAIN AND AN INHIBITOR OF MEMBRANE BINDING*

Factor VIII (FVIII) plays a critical role in blood coagulation by forming the tenase complex with factor IXa and calcium ions on a membrane surface containing negatively charged phospholipids. The tenase complex activates factor X during blood coagulation. The carboxyl-terminal C2 domain of FVIII is the main membrane-binding and von Willebrand factor-binding region of the protein. Mutations of FVIII cause hemophilia A, whereas elevation of FVIII activity is a risk factor for thromboembolic diseases. The C2 domain-membrane interaction has been proposed as a target of intervention for regulation of blood coagulation. A number of molecules that interrupt FVIII or factor V (FV) binding to cell membranes have been identified through high throughput screening or structure-based design. We report crystal structures of the FVIII C2 domain under three new crystallization conditions, and a high resolution (1.15 Å) crystal structure of the FVIII C2 domain bound to a small molecular inhibitor. The latter structure shows that the inhibitor binds to the surface of an exposed β-strand of the C2 domain, Trp²³¹³-His²³¹⁵. This result indicates that the Trp²³¹³-His²³¹⁵ segment is an important constituent of the membrane-binding motif and provides a model to understand the molecular mechanism of the C2 domain membrane interaction.     

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.