Ca2+ binding properties and Ca2(+)-dependent interactions of the isolated NH2-terminal alpha fragments of human complement proteases C1-r and C1-s.

The NH2-terminal alpha fragments of human complement proteases C1-r and C1-s were obtained by limited proteolysis of the native proteins with trypsin, and isolated. C1-r alpha extended from residues 1 to 208 of C1-r A chain, with at least two cleavage sites within disulfide loops, after lysine 134 and arginine 202. C1-s alpha comprised residues 1-192 of the C1-s A chain, with one cleavage site within a disulfide loop, after arginine 186. C1-r alpha was monomeric either in the presence or absence of Ca2+ but formed Ca2(+)-dependent dimers with native C1-s. C1-s alpha dimerized in the presence of Ca2+ and formed Ca2(+)-dependent tetramers (C1-s alpha-C1-r-C1-r-C1-s alpha) with native C1-r. C1-r alpha and C1-s alpha associated in the presence of Ca2+ to form C1-r alpha-C1-s alpha heterodimers. Equilibrium dialysis studies indicated that each alpha region binds Ca2+ with a dissociation constant ranging from 19 microM (native proteins) to 38 microM (fragments). C1-r alpha, C1-r alpha-C1-s alpha, and the native C1-s-C1-r-C1-r-C1-s tetramer bound 0.9, 1.9, and 4.0 Ca2+ atoms/mol, respectively, whereas dimers C1-s alpha-C1-s alpha and C1-s-C1-s incorporated 2.9 and 3.0 Ca2+ atoms/mol. It is concluded that each alpha region contains one high affinity Ca2+ binding site. This 1:1 stoichiometry is maintained upon heterologous (C1-r-C1-s) interaction, whereas the homologous (C1-s-C1-s) interaction provides one additional binding site.

Isolation and functional characterization of the proenzyme form of the catalytic domains of human C1r.

The proenzyme form of C1r catalytic domains was generated by limited proteolysis of native C1r with thermolysin in the presence of 4-nitrophenyl-4'-guanidinobenzoate. The final preparation, isolated by high-pressure gel permeation in the presence of 2 M-NaCl, was 70-75% proenzyme and consisted of a dimeric association of two gamma B domains, each resulting from cleavage of peptide bonds at positions 285 and 286 of C1r. Like native C1r, the isolated domains autoactivated upon incubation at 37 degrees C. Activation was inhibited by 4-nitrophenyl-4'-guanidinobenzoate but was nearly insensitive to di-isopropyl phosphorofluoridate; likewise, compared to pH 7.4, the rate of activation was decreased at pH 5.0, but was not modified at pH 10.0. In contrast, activation of the (gamma B)2 domains was totally insensitive to Ca2+. Activation of the catalytic domains, which was correlated with an irreversible increase of intrinsic fluorescence, comparable with that previously observed with native C1r [Villiers, Arlaud & Colomb (1983) Biochem. J. 215, 369-375], was reversibly inhibited at high ionic strength (2 M-NaCl), presumably through stabilization of a non-activatable conformational state. Detailed comparison of the properties of native C1r and its catalytic domains indicates that the latter contain all the structural elements that are necessary for intramolecular activation, but probably lack a regulatory mechanism associated with the N-terminal alpha beta region of C1r.

Differential accessibility of the carbohydrate moieties of Cls-Clr-Clr-Cls, the catalytic subunit of human Cl.

The catalytic subunit of human Cl, Cls-Clr-Clr-Cls, is a Ca2+-dependent tetrameric association of two serine proteases, Clr and Cls, which are glycoproteins containing asparagine-linked carbohydrates. With a view to investigate the accessibility and the possible functional role of these carbohydrates, the isolated proteases and their Ca2+-dependent complexes were submitted to deglycosylation by peptide:N-glycosidase F, an endoglycosidase that specifically hydrolyzes all classes of N-linked glycans. Treatment of isolated Clr and Cls led to the removal of the carbohydrate moieties attached to their N-terminal alpha region, whereas those located in the C-terminal gamma-B catalytic domains were resistant to hydrolysis. Formation of the Ca2+-dependent Cls-Cls dimer and Cls-Clr-Clr-Cls tetramer induced specific protection of the single carbohydrate attached to the alpha region of Cls and of one of the two carbohydrates located in the corresponding region of Clr. Sequence studies indicated that the carbohydrates protected upon homologous (Cls-Cls) or heterologous (Clr-Cls) interactions are attached to asparagine residues 159 of Cls and 204 of Clr, at the C-terminal end of the EGF-like domain of both proteases. These data bring further evidence that Ca2+-dependent interactions between Clr and Cls are mediated by their N-terminal alpha regions and strongly suggest that, inside these regions, the EGF-like domains play an essential role in these interactions.

Structural features of the first component of human complement, C1, as revealed by surface iodination.

Lactoperoxidase-catalysed surface iodination and sucrose-gradient ultracentrifugation were used to investigate the structure of human complement component C1. 1. Proenzymic subcomponents C1r and C1s associated to form a trimeric C1r2-C1s complex (7.6 S) in the presence of EDTA, and a tetrameric Clr2-C1s2 complex (9.1 S) in the presence of Ca2+. Iodination of the 9.1 S complex led to a predominant labelling of C1r (70%) over C1s (30%), essentially located in the b-chain moiety of C1r and in the a-chain moiety of C1s. 2. Reconstruction of proenzymic soluble C1 (15.2 S) from C1q, C1r and C1s was partially inhibited when C1s labelled in its monomeric form was used and almost abolished when iodinated C1r was used. Reconstruction of fully activated C1 was not possible, whereas hybrid C1q-C1r2-C1s2 complex was obtained. 3. Iodination of proenzymic or activated C1 bound to IgG-ovalbumin aggregates led to an equal distribution of the radioactivity between C1q and C1r2-C1s2. With regard to C1q, the label distribution between the three chains was similar whether C1 was in its proenzymic or activated form. Label distribution in the C1r2-C1s2 moiety of C1 was the same as that obtained for isolated C1r2-C1s2, and this was also true for the corresponding activated components. However, two different labelling patterns were found, corresponding to the proenzyme and the activated states.

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.