C1r and C1s from Nile tilapia (Oreochromis niloticus): Molecular characterization, transcriptional profiling upon bacterial and IFN-γ inductions and potential role in response to bacterial infection

The complement components C1r and C1s play a vital role in immunity with the activation of C1 complex in the classical complement pathway against pathogen infection. In this study, Nile tilapia (Oreochromis niloticus) C1r and C1s orthologs (OnC1r and OnC1s) were identified and characterized. The cDNA of OnC1r and OnC1s ORFs consisted of 1902 bp and 2100 bp of nucleotide sequence encoding polypeptides of 633 and 699 amino acids, respectively. The deduced OnC1r and OnC1s proteins both possessed CUB, EGF, CCP and SP domains, which were significantly homology to teleost. Spatial mRNA expression analysis revealed that the OnC1r and OnC1s were highly expressed in liver. After the in vivo challenges of Streptococcus agalactiae (S. agalactiae) and lipopolysaccharide (LPS), the mRNA expressions of OnC1r and OnC1s were significantly up-regulated in liver and spleen, which were consistent with immunohistochemical detection at the protein level. The up-regulation of OnC1r and OnC1s expressions were also demonstrated in head kidney monocytes/macrophages in vitro stimulated with LPS, S. agalactiae, and recombinant OnIFN-γ. Taken together, the results of this study indicated that OnC1r and OnC1s were likely to get involved in the immune response of Nile tilapia against bacterial infection.

Characterization of rock bream (Oplegnathus fasciatus) complement components C1r and C1s in terms of molecular aspects, genomic modulation, and immune responsive transcriptional profiles following bacterial and viral pathogen exposure

The complement components C1r and C1s play a crucial role in innate immunity via activation of the classical complement cascade system. As initiators of the pathogen-induced signaling cascade, C1r and C1s modulate innate immunity. In order to understand the immune responses of teleost C1r and C1s, Oplegnathus fasciatus C1r and C1s genes (OfC1r and OfC1s) were identified and characterized. The genomic sequence of OfC1r was enclosed with thirteen exons that represented a putative peptide with 704 amino acids (aa), whereas eleven exons of OfC1s represented a 691 aa polypeptide. In addition, genomic analysis revealed that both OfC1r and OfC1s were located on a single chromosome. These putative polypeptides were composed of two CUB domains, an EGF domain, two CCP domains, and a catalytically active serine protease domain. Phylogenetic analysis of C1r and C1s showed that OfC1r and OfC1s were evolutionary close to the orthologs of Pundamilia nyererei (identity = 73.4%) and Oryzias latipes (identity = 58.0%), respectively. Based on the results of quantitative real-time qPCR analysis, OfC1r and OfC1s transcripts were detected in all the eleven different tissues, with higher levels of OfC1r in blood and OfC1s in liver. The putative roles of OfC1r and OfC1s in response to pathogenic bacteria (Edwardsiella tarda and Streptococcus iniae) and virus (rock bream iridovirus, RBIV) were investigated in liver and head kidney tissues. The transcription of OfC1r and OfC1s was found to be significantly upregulated in response to pathogenic bacterial and viral infections. Overall findings of the present study demonstrate the potential immune responses of OfC1r and OfC1s against invading microbial pathogens and the activation of classical signaling cascade in rock bream.

Expression of recombinant human complement C1q allows identification of the C1r/C1s-binding sites

Complement C1q is a hexameric molecule assembled from 18 polypeptide chains of three different types encoded by three genes. This versatile recognition protein senses a wide variety of immune and nonimmune ligands, including pathogens and altered self components, and triggers the classical complement pathway through activation of its associated proteases C1r and C1s. We report a method for expression of recombinant full-length human C1q involving stable transfection of HEK 293-F mammalian cells and fusion of an affinity tag to the C-terminal end of the C chain. The resulting recombinant (r) C1q molecule is similar to serum C1q as judged from biochemical and structural analyses and exhibits the characteristic shape of a bunch of flowers. Analysis of its interaction properties by surface plasmon resonance shows that rC1q retains the ability of serum C1q to associate with the C1s-C1r-C1r-C1s tetramer, to recognize physiological C1q ligands such as IgG and pentraxin 3, and to trigger C1r and C1s activation. Functional analysis of rC1q variants carrying mutations of LysA59, LysB61, and/or LysC58, in the collagen-like stems, demonstrates that LysB61 and LysC58 each play a key role in the interaction with C1s-C1r-C1r-C1s, with LysA59 being involved to a lesser degree. We propose that LysB61 and LysC58 both form salt bridges with outer acidic Ca(2+) ligands of the C1r and C1s CUB (complement C1r/C1s, Uegf, bone morphogenetic protein) domains. The expression method reported here opens the way for deciphering the molecular basis of the unusual binding versatility of C1q by mapping the residues involved in the sensing of its targets and the binding of its receptors.

The initiating proteases of the complement system: controlling the cleavage

The complement system is a vital component of the host immune system, but when dysregulated, can also cause disease. The system is activated by three pathways: classical, lectin and alternative. The initiating proteases of the classical and lectin pathways have similar domain structure and employ similar mechanisms of activation. The C1r, C1s and MASP-2 proteases have the most defined roles in the activation of the system. This review focuses on the mechanisms whereby their interaction with substrates and inhibitors is regulated.

Elucidation of the Substrate Specificity of the C1s Protease of the Classical Complement Pathway

The complement system is a central component of host defense but can also contribute to the inflammation seen in pathological conditions. The C1s protease of the first complement component, the C1 complex, initiates the pathway. In this study we have elucidated the full specificity of the enzyme for the first time using a randomized phage display library. It was found that, aside from the crucial P(1) position, the S(3) and S(2) subsites (in that order) played the greatest role in determining specificity. C1s prefers Leu or Val at P(3) and Gly or Ala residues at P(2). Apart from the S(2)' position, which showed specificity for Leu, prime subsites did not greatly affect specificity. It was evident, however, that together they significantly contributed to the efficiency of cleavage of a peptide. A peptide substrate based on the top sequence obtained in the phage display validated these results and produced the best kinetics of any C1s substrate to date. The results allow an understanding of the active site specificity of the C1s protease for the first time and provide a basis for the development of specific inhibitors aimed at controlling inflammation associated with complement activation in adverse pathological situations.

The Structure of MBL-associated Serine Protease-2 Reveals that Identical Substrate Specificities of C1s and MASP-2 are Realized Through Different Sets of Enzyme–Substrate Interactions

A family of serine proteases mediates the proteolytic cascades of several defense mechanisms in vertebrates, such as the complement system, blood coagulation and fibrinolysis. These proteases usually form large complexes with other glycoproteins. Their common features are their modular structures and restricted substrate specificities. The lectin pathway of complement, where mannose-binding lectin (MBL) recognizes the carbohydrate structures on pathogens, is activated by mannose-binding lectin-associated serine protease-2 (MASP-2). We present the 2.25A resolution structure of the catalytic fragment of MASP-2 encompassing the second complement control protein module (CCP2) and the serine protease (SP) domain. The CCP2 module stabilizes the structure of the SP domain as demonstrated by differential scanning calorimetry measurements. The asymmetric unit contains two molecules with different CCP-SP domain orientations, reflecting increased modular flexibility at the CCP2/SP joint. This flexibility may partly explain the ability of the MASP-2 dimer to perform all of its functions alone, whereas the same functions are mediated by the much larger C1r2-C1s2 tetramer in the C1 complex of the classical pathway. The main scaffold of the MASP-2 SP domain is chymotrypsin-like. Eight surface loops determine the S1 and other subsite specificities. Surprisingly, some surface loops of MASP-2, e.g. loop 1 and loop 2, which form the S1 pocket are similar to those of trypsin, and show significant differences if compared with those of C1s, indicating that the nearly identical substrate specificities of C1s and MASP-2 are realized through different sets of enzyme-substrate interactions.

Prohaptoglobin is proteolytically cleaved in the endoplasmic reticulum by the complement C1r-like protein

Many secretory proteins are synthesized as proforms that become biologically active through a proteolytic cleavage in the trans-Golgi complex or at a later stage in the secretory pathway. Haptoglobin (Hp) is unusual in that it is cleaved in the endoplasmic reticulum before it enters the Golgi. Here, we present evidence that the recently discovered complement C1r-like protein (C1r-LP) mediates this cleavage. C1r-LP has not previously been shown to possess proteolytic activity, despite its homology to trypsin-like Ser proteinases. We demonstrate that coexpression of the proform of Hp (proHp) and C1r-LP in COS-1 cells effected cleavage of proHp in the endoplasmic reticulum. This cleavage depended on proteolytic activity of C1r-LP because mutation of the putative active-site Ser residue abolished the reaction. Furthermore, incubation of affinity-purified C1r-LP and proHp led to the cleavage of the latter protein. ProHp appeared to be cleaved at the expected site because substitution of Gly for Arg-161 blocked the reaction. C1r-LP showed specificity for proHp, in that it did not cleave the proform of complement C1s, a protein similar to Hp particularly around the cleavage site. C1r-LP accounts for at least part of the endogenous proHp-cleavage activity because suppression of the C1r-LP expression by RNA interference reduced the cleavage of proHp by up to 45% in the cells of a human hepatoma cell line (HepG2).

Structural and functional characterization of complement C4 and C1s-like molecules in teleost fish: insights into the evolution of classical and alternative pathways

There is growing evidence that certain components of complement systems in lower vertebrates are promiscuous in their modes of activation through the classical or alternative pathways. To better understand the evolution of the classical pathway, we have evaluated the degree of functional diversification of key components of the classical and alternative pathways in rainbow trout, an evolutionarily relevant teleost species. Trout C4 was purified in two distinct forms (C4-1 and C4-2), both exhibiting the presence of a thioester bond at the cDNA and protein levels. C4-1 and C4-2 bound in a similar manner to trout IgM-sensitized sheep erythrocytes in the presence of Ca(2+)/Mg(2+), and both C4 molecules equally restored the classical pathway-mediated hemolytic activity of serum depleted of C3 and C4. Reconstitution of activity was dependent on the presence of both C3-1 and C4-1/C4-2 and on the presence of IgM bound to the sheep erythrocytes. A C1s-like molecule was shown to cleave specifically purified C4-1 and C4-2 into C4b, while failing to cleave trout C3 molecules. The C1s preparation was unable to cleave trout factor B/C2 when added in the presence of C3b or C4b molecules. Our results show a striking conservation of the mode of activation of the classical pathway. We also show that functional interchange between components of the classical and alternative pathway in teleosts is more restricted than was anticipated. These data suggest that functional diversification between the two pathways must have occurred shortly after the gene duplication that gave rise to the earliest classical pathway molecules.

Importance of the Prime Subsites of the C1s Protease of the Classical Complement Pathway for Recognition of Substrates

The classical complement pathway, which plays a vital role in preventing infection, is initiated by the action of the serine proteases C1r and C1s. We have examined the hydrolysis of substrates representing cleavage sequences in the physiological substrates for C1s, C2 and C4. These studies showed that the P(1)'-P(4)' substrate residues of C2 and C4 conferred greater affinity of substrate for enzyme and also induced a sigmoidal dependence of enzyme velocity on substrate concentration. This indicates that the substrate gave rise to homotropic positive cooperative behavior in the enzyme. When C1s was in complex with C1q and C1r, as would occur under physiological conditions, the same behavior was observed, indicating that this mechanism is relevant in the complement pathway in vivo. We further investigated the requirements of C1s for prime side amino acids by examining a substrate library in which each of the P(1)'-P(4)' positions had been substituted by different classes of amino acids. This revealed that the P(1)' position was a major determinant of the selectivity of the enzyme, while certain substitutions at the P(1)'-P(4)' positions abolished the allosteric behavior, indicating that contact residues at these positions in the C1s enzyme must mediate the cooperativity. The studies reported here highlight the importance of prime subsites in C1s for interaction with its cognate substrates in the complement pathway and therefore yield greater understanding of the mechanism of interaction between this vital protease and its physiological substrates.

Origin of mannose-binding lectin-associated serine protease (MASP)-1 and MASP-3 involved in the lectin complement pathway traced back to the invertebrate, amphioxus

Mannose-binding lectin-associated serine proteases (MASPs) are involved in complement activation through the lectin pathway. To elucidate the phylogenetic origin of MASP and a primordial complement system, we cloned two MASP cDNAs from amphioxus (Branchiostoma belcheri) of the cephalochordates, considered to be the closest relative of vertebrates. The two sequences, orthologues of mammalian MASP-1 and MASP-3, were produced by alternative processing of RNA from a single gene consisting of a common H chain-encoding region and two L chain-encoding regions, a structure which is similar to that of the human MASP1/3 gene. We also isolated two MASP genes from the ascidian Halocynthia roretzi (urochordates) and found that each of them consists simply of an H chain-encoding region and a single L chain-encoding region. The difference in structure between the ascidian MASP genes and the amphioxus/mammalian MASP genes suggests that a prototype gene was converted to the MASP1/3-type gene possessing two L chain-encoding regions at an early stage of evolution before the divergence of amphioxus. This conclusion is supported by the presence of MASP-1 and MASP-3 homologues in almost all vertebrates, as demonstrated by the cloning of novel cDNA sequences representing lamprey (cyclostomes) MASP-1 and Xenopus MASP-3. The ancient origin of MASP-1 and MASP-3 suggests that they have crucial functions common to all species which emerged after cephalochordates.

C1s, the protease messenger of C1. Structure, function and physiological significance

C1s is the modular serine protease, which executes the catalytic function of the C1 complex: the cleavage of C4 and C2. Like other complement serine proteases C1s has restricted substrate specificity and it is engaged into specific interactions with other subcomponents of the complement system. There has been a rapid progress in determining the 3D structure of complement serine proteases and in revealing the role of the individual domains in the protein-protein interaction properties. In this review we summarize recent findings on the structure of C1s, and on the mechanism of action of this protease. The results obtained by genetic engineering, physico-chemical and functional studies are reviewed. The physiological relevance of the proteolytic action of C1s and its possible implications in health and disease will also be discussed.

Structure, function and molecular genetics of human and murine C1r

C1r, the enzyme responsible for intrinsic activation of the C1 complex of complement, is a modular serine protease featuring an overall structural organization homologous to those of C1s and the mannan-binding lectin-associated serine proteases (MASPs). This review will initially summarize current information on the structure and function of C1r, with particular emphasis on the three-dimensional structure of its catalytic domain, which provides new insights into the activation mechanism of C1. The second part of this review will focus on recent discoveries dealing with a truncated, C1r-related protein, and the occurrence in the mouse of two isoforms, C1rA and C1rB, exhibiting tissue-specific expression patterns.

Structural biology of C1: dissection of a complex molecular machinery

The classical pathway of complement is initiated by the C1 complex, a multimolecular protease comprising a recognition subunit (C1q) and two modular serine proteases (C1r and C1s) associated as a Ca2+-dependent tetramer (C1s-C1r-C1r-C1s). Early studies have allowed identification of specialized functional domains in these proteins and have led to low-resolution models of the C1 complex. The objective of current studies is to gain deeper insights into the structure of C1, and the strategy used for this purpose mainly consists of dissecting the C1 components into modular fragments, in order to solve their three-dimensional structure and establish the structural correlates of their function. The aim of this article is to provide an overview of the structural and functional information generated by this approach, with particular emphasis on the domains involved in the assembly, the recognition function, and the highly specific proteolytic properties of C1.

The complement component C1s is the protease that accounts for cleavage of insulin-like growth factor-binding protein-5 in fibroblast medium

Cultured fibroblasts secrete an 88-kDa serine protease that cleaves insulin-like growth factor binding protein-5 (IGFBP-5). Because IGFBP-5 has been shown to regulate IGF-I actions, understanding the chemical identity and regulation of this protease is important for understanding how IGF-I stimulates anabolic functions. The protease was purified from human fibroblast-conditioned medium by hydrophobic interaction, lectin affinity, and heparin Sepharose affinity chromatography followed by SDS-polyacrylamide gel electrophoresis. An 88-kDa band was excised and digested with lysyl-endopeptidase. Sequencing of the high pressure liquid chromatography-purified peptides yielded the complement components C1r and C1s. To confirm that C1r/C1s accounted for the proteolytic activity in the medium, immunoaffinity chromatography was performed. Most of the protease activity adhered to the column, and the eluant was fully active in cleaving IGFBP-5. SDS-polyacrylamide gel electrophoresis with silver staining showed two bands, and IGFBP-5 zymography showed a single 88-kDa band. Amino acid sequencing confirmed that the 88-kDa band contained only C1r and C1s. C1r in the fibroblast medium underwent autoactivation, and the activated form cleaved C1s. C1s purified from the conditioned medium cleaved C(4), a naturally occurring substrate. The purified protease cleaved IGFBP-5 but had no activity against IGFBP-1 through -4. C1 inhibitor, a protein known to inhibit activated C1s, was shown to inhibit the cleavage of IGFBP-5 by the protease in the conditioned medium. In summary, human fibroblasts secrete C1r and C1s that actively cleave IGFBP-5. The findings define a mechanism for cleaving IGFBP-5 in the culture medium, thus allowing release of IGF-I to cell surface receptors.

The cleavage of two C1s subunits by a single active C1r reveals substantial flexibility of the C1s-C1r-C1r-C1s tetramer in the C1 complex

The activation of the C1s-C1r-C1r-C1s tetramer in the C1 complex, which involves the cleavage of an Arg-Ile bond in the catalytic domains of the subcomponents, is a two-step process. First, the autolytic activation of C1r takes place, then activated C1r cleaves zymogen C1s. The Arg463Gln mutant of C1r (C1rQI) is stabilized in the zymogen form. This mutant was used to form a C1q-(C1s-C1rQI-C1r-C1s) heteropentamer to study the relative position of the C1r and C1s subunits in the C1 complex. After triggering the C1 by IgG-Sepharose, both C1s subunits are cleaved by the single proteolytically active C1r subunit in the C1s-C1rQI-C1r-C1s tetramer. This finding indicates that the tetramer is flexible enough to adopt different conformations within the C1 complex during the activation process, enabling the single active C1r to cleave both C1s, the neighboring and the sequentially distant one.

Crystal structure of the catalytic domain of human complement c1s: a serine protease with a handle

C1s is the highly specific modular serine protease that mediates the proteolytic activity of the C1 complex and thereby triggers activation of the complement cascade. The crystal structure of a catalytic fragment from human C1s comprising the second complement control protein (CCP2) module and the chymotrypsin-like serine protease (SP) domain has been determined and refined to 1.7 A resolution. In the areas surrounding the active site, the SP structure reveals a restricted access to subsidiary substrate binding sites that could be responsible for the narrow specificity of C1s. The ellipsoidal CCP2 module is oriented perpendicularly to the surface of the SP domain. This arrangement is maintained through a rigid module-domain interface involving intertwined proline- and tyrosine-rich polypeptide segments. The relative orientation of SP and CCP2 is consistent with the fact that the latter provides additional substrate recognition sites for the C4 substrate. This structure provides a first example of a CCP-SP assembly that is conserved in diverse extracellular proteins. Its implications in the activation mechanism of C1 are discussed.

Structure and functions of the interaction domains of C1r and C1s: keystones of the architecture of the C1 complex

C1r and C1s, the proteases responsible for activation and proteolytic activity of the C1 complex of complement, share similar overall structural organizations featuring five nonenzymic protein modules (two CUB modules surrounding a single EGF module, and a pair of CCP modules) followed by a serine protease domain. Besides highly specific proteolytic activities, both proteases exhibit interaction properties associated with their N-terminal regions. These properties include the ability to bind Ca2+ ions with high affinity, to associate with each other within a Ca2+-dependent C1s-C1r-C1r-C1s tetramer, and to interact with C1q upon C1 assembly. Precise functional mapping of these regions has been achieved recently, allowing identification of the domains responsible for these interactions, and providing a comprehensive picture of their structure and function. The objective of this article is to provide a detailed and up-to-date overview of the information available on these domains, which are keystones of the assembly of C1, and appear to play an essential role at the interface between the recognition function of C1 and its proteolytic activity.

Molecular basis of human complement C1s deficiency

This is the first report on the molecular basis of human complement C1s deficiency. Two abnormalities in the C1s gene were identified in a Japanese family, including one patient, by using exon-specific PCR, single-strand conformation polymorphism analysis, and nucleotide sequencing. A deletion of 4 bp, TTTG, was identified in exon X when using genomic DNA from the patient, his father, and his paternal grandmother. They were all heterozygous for the mutation. The mutant gene encodes a truncated C1s from the N terminus to the short consensus repeat domain. By further sequencing the PCR products, a nonsense mutation from G to T was identified at codon 608 in exon XII in the patient, his mother, and his sister. They were all heterozygous for the nonsense mutation. The mutant gene encodes a truncated form of C1s that lacks the C-terminal 80 amino acids. These results indicate that the patient was a compound heterozygote with the 4-bp deletion on the paternal allele and the nonsense mutation on the maternal allele. The levels of serum C1s seem to be correlated to the genotypes of the C1s gene in which no C1s was detected in the patient, and one-half of the normal level in the family members who are heterozygous for either mutation. The present study demonstrates that the disease is inherited in an autosomal recessive mode.

Structural and functional studies on C1r and C1s: new insights into the mechanisms involved in C1 activity and assembly

C1r and C1s, the enzymes responsible for the activation and proteolytic activity of the C1 complex of complement, are modular serine proteases featuring similar overall structural organizations, yet expressing very distinct functional properties within C1. This review will initially summarize available information on the structure and function of the protein modules and serine protease domains of C1r and C1s. It will then focus on the regions of both proteases involved in: (i) assembly of C1s-C1r-C1r-C1s, the Ca(2+)-dependent tetrameric catalytic subunit of C1; (ii) expression of C1 catalytic activities. Particular emphasis will be aid on recent structural and functional studies that provide new insights into the complex mechanisms involved in the assembly, activation, and proteolytic activity of C1.

MASP-2, the C3 convertase generating protease of the MBLectin complement activating pathway

Mannan-binding lectin (MBL) activates the complement system through cleavage of C4 and C2. Until recently it was thought that only one serine protease in complex with MBL (MBL-associated serine protease, MASP) mediates complement activation, but with the finding of a second MBL-associated serine protease, MASP-2, the activation process appears more elaborate, possibly resembling that of the C1 complex. The two MASPs share the domain organisation of C1r and C1s and it may be speculated that interaction between the two MASPs is required for complement activation in the same manner as with the C1 proteases. We have demonstrated that MASP-2 is a C4 cleaving component of the MBL/MASP complex. By analogy, one may thus speculate that, upon binding of MBL to carbohydrate, MASP-1 autoactivates and then activates MASP-2, but there is as yet no evidence for this. The components of C1 are present in serum in approximately equimolar amounts, whereas MASP-1 is in large excess over MBL. Pairwise comparison of the four proteases shows the primary structures to be approximately 40% identical. Phylogenetic analysis indicates that MASP-2 is closer to C1r and C1s than is MASP-1, but no particular association between MASP-2 and the C4 cleaving enzyme, C1s, can be deduced from sequence comparison.

Structure and function of the serine-protease subcomponents of C1: protein engineering studies

Our protein engineering studies on human C1r and C1s revealed important characteristics of the individual domains of these multidomain serine-proteases, and supplied evidence about the cooperation of the domains to create binding sites, and to control the activation process. We expressed the recombinant subcomponents in the baculovirus-insect cell system and checked the biological activity. Deletions and point mutants of C1r were constructed and C1r-C1s chimeras were also produced. Our deletion mutants demonstrated that the N-terminal CUB domain and the EGF-like domain of C1r together are responsible for the calcium dependent C1r-C1s interaction. It seems very likely that these two modules form the calcium-binding site of the C1r alpha-fragment and participate in the tetramer formation. The deletion mutants also demonstrated that the N-terminal region of the C1r molecule contains essential elements involved in the control of activation of the serine-protease module. The substrate specificity of the serine-protease is also determined by the five N-terminal noncatalytic domain of C1r/C1s chimera, which contains the catalytic domain of C1s preceded by the N-terminal region of C1r, could replace the C1r in the hemolytically active C1 complex. The C1s/C1r chimera, in which the alpha-fragment of the C1r was replaced for that of the C1s exibits both C1r- and C1s-like characteristics. We stabilized the zymogen form of human C1r by mutating the Arg(463)-Ile(464) bond. Using our stable zymogen C1r we showed that one active C1r in the C1 complex is sufficient for the full activity of the entire complex. Further experiment with this mutant could provide us with important information about the structure of the C1 complex.

Molecular cloning of a cDNA encoding a serine protease homologous to complement C1s precursor from rat C6 glial cells and its expression during glial differentiation

A cDNA of rat C6 cells was cloned, which was considered to be involved in glial cell differentiation induced by dibutyryl cyclic AMP and theophylline. The cDNA fragment of the gene, termed r-gsp, was originally isolated by mRNA fingerprinting using arbitrarily primed polymerase chain reaction, and was homologous to complement C1s precursors of hamster and human. It encodes a protein of 694 amino acids containing a potential signal peptide, an epidermal growth factor-like domain surrounded by two complement C1r/C1s-related repeats, and a putative trypsin-type serine protease domain. Since the hamster and human C1s, and a protein encoded by r-gsp shared high similarity in primary structure, the r-gsp gene could encode a C1s counterpart of the rat. Messenger RNA expression of this gene was markedly increased during cyclic AMP-induced glial cell differentiation. Its expression profile was well correlated with those of glial fibrillary acidic protein (GFAP) and S100B, which are known as glial differentiation markers. It was, moreover, observed that the r-gsp expression in brain increased considerably after birth, like those of S100B and GFAP. The results presented here suggest that the rat C1s gene would be also implicated in glial differentiation besides the complement cascade.

NMR structures of the C-terminal end of human complement serine protease C1s

Synthetic peptides derived from the C-terminal end of the human complement serine protease C1s were analysed by circular dichroism and nuclear magnetic resonance (NMR) spectroscopy. Circular dichroism indicates that peptides 656-673 and 653-673 are essentially unstructured in water and undergo a coil-to-helix transition in the presence of increasing concentrations of trifluoroethanol. Two-dimensional NMR analyses performed in water/trifluoroethanol solutions provide evidence for the occurrence of a regular alpha-helix extending from Trp659 to Ser668 (peptide 656-673), and from Tyr656 to Ser668 (peptide 653-673), the C-terminal segment of both peptides remaining unstructured under the conditions used. Based on these and other observations, we propose that the serine protease domain of C1s ends in a 13-residue alpha-helix (656Tyr-Ser668) followed by a five-residue C-terminal extension. The latter appears to be flexible and is probably locked within C1s through a salt bridge involving Glu672.

Complement Cls, a classical enzyme with novel functions at the endochondral ossification center: immunohistochemical staining of activated Cls with a neoantigen-specific antibody

The secondary ossification center of 14- to 16-day-old hamster tibiae was examined immunohistochemically with active and inactive Cls-specific antibodies, RK5 and RK4, respectively. At the ossification center, chondrocytes differentiate from proliferating and hypertrophic to degenerating stages, and their site is occupied by the bone marrow. Cls was strongly immunostained in hypertrophic chondrocytes. In order to discover whether Cls is activated at a particular site, the cartilage was immunostained with RK5 and RK4. RK5 mainly reacted with degrading matrix around invading vessels. In contrast, RK4 strongly stained hypertrophic chondrocytes. Immunoelectron microscopy revealed Cls on degrading fragments of chondrocytes and fibers of cartilage matrix. Decorin, one of the major matrix proteoglycans, was dose and time dependently degraded by Cls. Type II collagen and type I gelatin were also degraded. Articular cartilage from patients with rheumatoid arthritis was positively immunostained (11/12 cases) with an anti-Cls monoclonal antibody (mAb) PG11, whereas normal articular cartilage (5/5 cases) was negative, suggesting Cls participation in the etiology of rheumatoid arthritis.

Chemical synthesis and characterization of the epidermal growth factor-like module of human complement protease C1r

C1r is one of the two serine proteases of C1, the first component of complement, in which it is associated in a calcium-dependent manner to the homologous serine protease C1s. This interaction is mediated by the N-terminal region of C1r, which comprises a single epidermal growth factor (EGF)-like module containing the consensus sequence required for calcium binding, surrounded by two CUB modules. With a view to determine the structure of the EGF-like module of C1r and evaluate its contribution to calcium binding, this module [C1r(123-175)] was synthesized by automated solid-phase methodology using the Boc strategy. A first synthesis using the Boc-His(Z) derivative gave very low yield, due to partial deprotection of His residues leading to chain termination by acetylation, and to insertion of glycine residues. This could be circumvented by using the Boc-His(DNP) derivative and by condensation of appropriate glycine-containing segments. The synthetic peptide was efficiently folded under redox conditions to the species with three correct disulfide bridges, as determined by mass spectrometry and N-terminal sequence analyses of thermolytic fragments. The homogeneity of the synthetic peptide was assessed by reversed-phase HPLC and electrospray mass spectrometry. One-dimensional 1H NMR spectroscopic analysis provided evidence that the EGF-like module had a well defined structure, and was able to bind calcium with an apparent Kd of 10 mM. This value, comparable to that found for the isolated EGF-like modules of coagulation factors IX and X, is much higher than that measured for native C1r. As already proposed for factors IX and X, it is suggested that neighbouring module(s), most probably the N-terminal CUB module, contribute(s) to the calcium binding site.

Exon structure of the gene encoding the human mannose-binding protein-associated serine protease light chain: comparison with complement C1r and C1s genes

Mannan or mannose-binding protein (MBP) requires a novel serine protease termed MBP-associated serine protease (MASP) for activation of the complement cascade. In this study, we analyzed MASP genomic clones and found that the light chain (catalytic domain) is encoded by six exons, whereas those of the complement C1 subunits, C1r and C1s, and the haptoglobin segment have been reported to be encoded by a single exon. We confirmed the intron-lacking sequence of C1r by analysis of its genome. These results, in conjunction with those obtained by constructing a phylogenetic tree for these proteins, suggest that the MASP gene is prototype and that the intron-lacking sequences of the other serine proteases have a more recent history.

The catabolism of intact, reactive centre-cleaved and proteinase-complexed C1 inhibitor in the guinea pig

Clearance rates in the guinea pig were determined for intact guinea pig and human C1 inhibitor, the complexes of both inhibitors with human Cls, beta factor XIIa and kallikrein, and for each inhibitor cleaved at its reactive centre with trypsin. Intact human and guinea pig C1 inhibitor were cleared from the circulation more slowly (t1/2s of 9-7 h and 12.1 h and fractional catabolic rates (FCRs) of 0.09 and 0.117) than any of their cleaved or complexed forms. The reactive centre-cleaved inhibitors were cleared with half-lives of 6.75 h for humans and 10.1 h for the guinea pig. The complexes with target proteases were catabolized much more rapidly, with half-lives ranging from 3-08 h to 4.3 h. The complexes with kallikrein were cleared more slowly than those with Cls and beta factor XIIa. Complexes prepared with the guinea pig and human inhibitors were cleared at equivalent rates. The free inactivated proteases were cleared at rates similar to the equivalent complexes, except for kallikrein, which was cleared more rapidly than its complex. The fact that the complexes with different target proteases differed in their catabolism and that protease and complex catabolism were similar suggests that protease may play a direct role in clearance.

Site-directed mutagenesis of hamster complement C1S: characterization with an active form-specific antibody and possible involvement of C1S in tumorigenicity

We have previously shown that non-transformed mouse A31 cells became tumorigenic when they were transfected with hamster C1s cDNA expression plasmid BCMGSNeoCS. In the present study, mutations were introduced into the cDNA at the activation cleavage site, Arg423(AGG) and the active center Ser617(AGC). These amino-acids were replaced by His423(CAC) and Thr617(ACC), respectively. The mutated cDNAs were inserted into BCMGSNeo and transfected to A31 and its polyoma-virus-transformed SEA7 cells. C1s produced from these transfectants lost their enzyme activity. Transfectants of these mutated C1s cDNA did not form tumors in nude mice, To distinguish between active and inactive C1s in situ, we have developed novel antibodies, one directed to the NH2-terminal neoepitope of the L chain and the other specific for uncleaved inactive C1s. These antibodies were used to characterize C1s produced by transfectants, so as to determine whether or not it was cleaved at the right position.

Purification and characterization of recombinant hamster tissue complement C1s

Hamster complement C1s cDNA was inserted into expression plasmid BCMGSNeo, and transfected to SEA7 cells, A31 mouse fibroblasts transformed by polyoma virus. The transfectant secreted a large amount of recombinant C1s that was activated in the serum free culture medium and hydrolyzed acetyl-Gly-L-Lys-naphthyl ester (AGLNE). C1s was purified to a homogeneity from the culture medium of the transfectant by DEAE-Sephadex, Dymatrex orange A and size-exclusion HPLC. Purified hamster C1s consumed human complement in hemolytic assay and hydrolyzed gelatin in enzymography. To investigate the enzymic action of C1s at molecular levels, several antibodies were prepared against hamster C1s. One peptide (amino-acid residues 379-391) and two peptides (amino-acid residues 478-496 and 560-583) corresponding to the heavy and the light chain, respectively, were synthesized. The amino-acid sequences of these regions is not conserved between hamster and human C1s. Antibodies against these peptides were raised in rabbits. The anti-peptide antibodies bound specifically to hamster serum and recombinant C1s but not to human C1s. They inhibited the esterase activity of recombinant C1s to varying degrees depending on each antibody's binding site.

Structure of the catalytic region of human complement protease C1s: study by chemical cross-linking and three-dimensional homology modeling

C1s is a multidomain serine protease that is responsible for the enzymatic activity of C1, the first component of the classical pathway of complement. Its catalytic region (gamma-B) comprises two contiguous complement control protein (CCP) modules, IV and V (about 60 residues each), a 15-residue intermediary segment, and the B chain (251 residues), which is the serine protease domain. With a view to identify domain-domain interactions within this region, the gamma-B fragment of C1s, obtained by limited proteolysis with plasmin, was chemically cross-linked with the water-soluble carbodiimide 1-ethyl-3-[3-(dimethylamino)propyl]carbodiimide; then cross-linked peptides were isolated after CNBr cleavage and thermolytic digestion. N-Terminal sequence and mass spectrometry analyses allowed us to identify two cross-links between Lys 405 of module V and Glu 672 of the B chain and between Glu 418 of the intermediary segment and Lys 608 of the B chain. Three-dimensional modeling of the CCP modules IV and V and of the catalytic B chain was also carried out on the basis of their respective homology with the 16th and 5th CCP modules of complement factor H and type I serine proteases. The information provided by both the chemical cross-linking studies and the homology modeling enabled us to construct a three-dimensional model for the assembly of the C-terminal part of the gamma-B region, comprising module V, the intermediary segment, and the B chain. This model shows that module V interacts with the serine protease B chain on the side opposite to both the activation site and the catalytic site. Functional implications of this interaction are discussed in terms of the possible role of module V in the specific recognition and positioning of C4, one of the two substrates of C1s.

Analysis of the N-linked oligosaccharides of human C1s using electrospray ionisation mass spectrometry

Information on the structures of the oligosaccharides linked to Asn residues 159 and 391 of the human complement protease C1s was obtained using mass spectrometric and monosaccharide analyses. Asn159 is linked to a complex-type biantennary, bisialylated oligosaccharide NeuAc2 Gal2 GlcNAc4 Man3 (molecular mass = 2206 +/- 1). Asn391 is occupied by either a biantennary, bisialylated oligosaccharide, or a triantennary, trisialylated species NeuAc3 Gal3 GlcNAc5 Man3 (molecular mass = 2861 +/- 1), or a fucosylated triatennary, trisialylated species NeuAc3 Gal3 GlcNAc5 Man3 Fuc1 (molecular mass = 3007 +/- 1), in relative proportions of approximately 1:1:1. The carbohydrate heterogeneity at Asn391 gives rise to three major types of C1s molecules of molecular masses 79,318 +/- 8 (A), 79,971 +/- 8 (B), and 80,131 +/- 8 (C), with an average mass of 79,807 +/- 8. A minor modification, yielding an extra mass of 132 +/- 2, is also detected within positions 1-153.

Functional analysis of the serpin domain of C1 inhibitor

To analyze the role of the heavily glycosylated amino-terminal domain of C1 inhibitor in protease inhibitory activity, two truncated C1 inhibitor molecules were constructed. The abilities of the recombinant truncated inhibitors to complex with target proteases were compared with that of the wild-type recombinant protein. One recombinant truncated molecule consisted of amino acid residues 76 to 478 (C-serp(76)) and the other of residues 98 to 478 (C-serp(98)). The recombinant proteins were each expressed in similar quantities. The thermal denaturation profiles of the two truncated proteins were similar to that of the wild-type protein. Identical binding of C1s, C1r, kallikrein, and beta factor XIIa was observed with the three molecules. Furthermore, the truncated molecules also effectively inhibited C1 activity in hemolytic assays. These studies therefore clearly demonstrate that the amino-terminal domain of C1 inhibitor does not influence complex formation with target proteases.

Chemical characterization and location of ionic interactions involved in the assembly of the C1 complex of human complement

The C1 complex of human complement comprises two loosely interacting subunits, C1q and the Ca(2+)-dependent C1s-C1r-C1r-C1s tetramer. With a view to gain information on the nature of the ionic interactions involved in C1 assembly, we have studied the effects of the chemical modifications of charged residues of C1q or the tetramer on their ability to reconstitute the C1 complex. Treatment of C1q with pyridoxal-5'-phosphate, acetic anhydride, and citraconic anhydride, as well as with cyclohexanedione and diethylpyrocarbonate, inhibited its ability to associate with C1s-C1r-C1r-C1s. Treatment of the collagen-like fragments of C1q with the same reagents yielded the same effects. Treatment of C1s-C1r-C1r-C1s with 1-ethyl-3-[-3-(dimethylamino) propyl] carbodiimide also prevented C1 assembly, through modification of acidic amino acids which were shown to be located in C1r. Further studies on the location of the interaction sites within C1q, using ligand-blotting and competition experiments with synthetic peptides, were unsuccessful, suggesting that these sites are contributed to by two or three of the C1q chains. It is concluded that C1 assembly involves interactions between acidic amino acids of C1r and lysine (hydroxylysine) and arginine residues located within the collagen-like region of C1q. Sequence comparison with mannan binding protein, another collagen-like molecule which binds the C1s-C1r-C1r-C1s tetramer, suggests Arg A38, and HyL B32, B65, and C29 of C1q as possible interaction sites.

Protein engineering studies on C1r and C1s

1. C1r and C1s cDNAs were placed downstream the strong polyhedrin promoter in the Autographa californica nuclear polyhedrosis virus and the recombinant proteins were expressed in insect cells, in biologically active form. The yield of expression is high enough to get recombinant components for chemical and functional studies (5 micrograms/ml cell culture supernatant). 2. The biological activity and the post-translational modifications of the recombinant subcomponents were checked. The rC1r and rC1s proved to be biologically active in the hemolytic assay, although their glycosylations were different compared to that of the serum proteins. The insect cells are able to beta-hydroxylate the Asn residue of the EGF domain in the C1r but with a low efficiency. It is clear now, that this post-translational modification does not play a role in the Ca2+ dependent C1r-C1s interaction. 3. Two deletion mutants of C1r cDNA were constructed in order to clarify the role of domain I and II. The results show that both, domain I, and II are absolutely necessary for the tetramer formation and both have a regulatory role in the autoactivation. The autoactivation of the mutants is accelerated significantly. 4. Hybrid cDNA constructions were also made, and one of them was expressed. In the C1s alpha R hybrid the C1s alpha part cannot dimerize in presence of Ca2+, but it can form a tetramer with C1r2, that can bind to C1q. This observation indicates that the function of the C1s alpha part in the hybrid is modulated by the C1r part (gamma B) of the molecule. 5. In order to control the autoactivation process point mutant cDNAs were constructed through altering the Arg-Ile bond in the catalytic domain of the C1r. The Gln-Ile construction is a stable zymogen while the Arg-Phe mutant has a lower rate of autoactivation. These results do justify our approach of using domain-domain interchange, domain deletion and point mutations in combination, to reveal the structural background of C1 function at intramolecular level.

C1 subcomponent complexes: basic and clinical aspects

C1 subcomponents form a variety of complexes that can be detected in normal and pathological sera. Since aberrations of C1 subcomponents in disease could reflect in vivo interactions with influence on complement function, studies of C1 subcomponent complexes might provide insight into pathogenetic mechanisms. C1 inhibitor (C1Inh)-dependent dissociation of the C1q(C1r-C1s)2 complex gives rise to C1Inh-C1r-C1s or C1Inh-C1r-C1s-C1Inh complexes. Increased concentrations of C1Inh-C1r-C1s probably signify prevention of C1 activation, while C1Inh-C1r-C1s-C1Inh appears to be a clinically useful marker of efficient classical pathway activation. "Free" C1q as found in some pathological sera, and in joint fluids of patients with rheumatoid arthritis could be a result of C1Inh-dependent dissociation of C1q(C1r-C1s)2. The presence in serum of zymogen (C1r-C1s)2 is an expected finding in various conditions with low C1q concentrations without evidence of C1 activation. It is not excluded that circulating (C1r-C1s)2 might sometimes be acquired due to factors capable of interacting with the collagenous part of the C1q molecule.

Assembly of the C1 complex

The C1 complex of complement is a Ca(2+)-dependent complex protease comprising two loosely interacting subunits. C1q, the recognition subunit, is an hexameric protein with six peripheral globular domains, each connected through collagen-like "arms" to a central fibril-like "stalk". The catalytic subunit, C1s-C1r-C1r-C1s, is a Ca(2+)-dependent tetrameric association of two serine protease zymogens, C1r and C1s, that are sequentially activated by cleavage of a single peptide bond, upon binding of C1 to activators. Each monomeric protease is comprised of six structural motifs which form at least four domains, distributed in two functionally distinct regions, alpha (N-terminal) and gamma-B (C-terminal). The catalytic (gamma-B) regions of C1r and C1s are respectively located in the centre and at each end of the isolated tetramer, and the Ca(2+)-dependent C1r-C1s associations are mediated by the interaction (alpha) regions, which contain one Ca2+ binding site each. Physicochemical and electron microscopy studies indicate that the tetramer, which is highly elongated, folds into a more compact conformation upon interaction with C1q. Various models for C1 have been proposed, in which the tetramer either interacts with the outside part of the C1q arms (O- and W-shaped models), or is folded within the C1q arms (S- or 8-shaped models). These models are discussed in light of available information and in consideration of the structural requirements of C1 activation and function.

Identity of the putative serine-proteinase fold in proteins of the complement system with nine relevant crystal structures

The serine-proteinase domain is responsible for the proteolytic events that occur during complement activation. The sequences of nine serine proteinases of known crystal structure were compared with the serine-proteinase sequences in the six complement proteins C1r, C1s, C2, factor B, factor I and factor D to assess the degree of structural homology of the latter with the crystal structures. All sequence insertions and deletions were readily located at the protein surface. The internal location of disulphide bridges and the surface location of putative glycosylation sites are compatible with this structure. Secondary-structure predictions for the sequences were fully consistent with the crystal structures. It is concluded that the double subdomain beta-sheet motif is retained in the complement sequences, but that localized differences are observed for factor I, C2 and factor B.

Calcium-linked self-association of human complement C1s

The weight-average molecular weight of C1s, an activated serine protease subcomponent of human complement C1, has been measured by means of sedimentation equilibrium over a wide range of both protein and calcium ion concentrations. The combined data may be accounted for quantitatively by a simple model for Ca(2+)-dependent self-association of C1s to a dimer. According to this model, the monomer contains a single Ca2+ binding site with K approximately equal to 3 x 10(5) M-1, and the dimer contains three independent Ca binding sites, two having a Ca2+ affinity lower than that of the monomer (K approximately equal to 3 x 10(4) M-1). The third binding site in the dimer, which presumably lies at the interface between the two amino-terminal alpha domains, has a higher Ca2+ affinity (K approximately equal to 1 x 10(8) M-1) and provides the driving force for C1s dimerization in the presence of calcium.

Recombinant human complement subcomponent C1s lacking beta-hydroxyasparagine, sialic acid, and one of its two carbohydrate chains still reassembles with C1q and C1r to form a functional C1 complex

In contrast to the human serum protein which is approximately one-half erythro-beta-hydroxyasparagine at asparagine 134 [Theilens et al. (1990) Biochemistry 29, 3570-3578], recombinant C1s expressed by insect cells after infection with recombinant baculovirus entirely lacks posttranslational modification at asparagine 134. It is also incompletely glycosylated, lacking, at least, sialic acid. Site-directed mutagenesis of one of the two sites of carbohydrate attachment (Asn 159 to Gln 159) yields a faster migrating recombinant C1s still abundantly secreted. Furthermore, the mutated protein displays good hemolytic activity when reassembled with C1q and either human serum or recombinant C1r, demonstrating that these posttranslational modifications are not critical for any of the multiple interactions between C1s and C1q, C1r, C2, and C4 required for reassembly of the C1 complex, activation, and initiation of the classical complement pathway. The 4.0S recombinant C1s dimerizes to yield 5.6S C1s2 in the presence of Ca2+ and forms the 9.1S C1s-C1r-C1r-C1s tetramer upon the addition of human serum C1r and the 15.6S C1 complex upon the addition of C1q to the tetramer. The recombinant C1s and human serum C1s have identical N-terminal amino acid sequences, indicating proper recognition by the insect signal peptidase. The recombinant C1s is secreted and isolated as the unactivated zymogen, and it may be activated by human serum C1r which cleaves at Arg422-Ile423 to yield the characteristic heavy and light chains. A very tight complex is formed between C1-inhibitor and the light chain of recombinant C1s.(ABSTRACT TRUNCATED AT 250 WORDS)

Dynamic equilibria between subcomponents of C1, the first component of human complement

C1r and C1s, the serine protease components of activated C1, form a tetramer in the presence of Ca2+. The stability of this tetramer is sufficient that its association with the third component, C1q, has been successfully treated as a reversible bimolecular equilibrium reaction [Siegel and Schumaker, Molec. Immun. 20, 53-66 (1983)]. We have used the fluorescence anisotropy (A) of fluorescein-labeled C1s (s*) to monitor assembly and subcomponent exchange in 0.15 mol/l NaCl, 0.001 mol/l Ca2+ 0.02 mol/l Tris, pH 7.4. Addition of q to r2s*2 causes a small but measurable delta A of 0.01-0.02. The response is too fast to measure at 37 degrees but can be readily followed at 4 degrees where t 1/2 = 0.6 min when [q] = [r2s*2] = 0.5 mumol/l. The increase in A can be readily reversed by dilution or by addition of unlabeled C1s. Slow incremental addition of q to a solution of r2s*2 produces a dose-dependent delta A from which stoichiometry and dissociation constants can be derived. Measurements of Kd as a function of temperature establish an inverse temperature dependence with delta H = -15 kcal/mol and a value of Kd = 0.031 mumol/l at 37 degrees (delta G = + 11, T delta S = -26 kcal/mol). Thus, the assembly process appears to be entropy-driven presumably due to the exclusion of structured water from protein-protein interfaces in the complex.

Complement components C1r/C1s, bone morphogenic protein 1 and Xenopus laevis developmentally regulated protein UVS.2 share common repeats

Property patterns were constructed, based on an alignment of related domains in human complement subcomponents C1r and C1s as well as in the sea urchin protein uEGF. This kind of consensus pattern was able to identify similar domains in a human bone morphogenic protein, in a Xenopus laevis embryonal protein involved in dorsoanterior development and in a calcium-dependent serine protease secreted from malignant hamster embryo fibroblast cells. Because of the high level of overall sequence homology this protease may be the hamsters' equivalent of the human complement subcomponent C1s. The resulting multiple alignment of all studied domains suggests functionally and structurally important regions.

Identification of the disulfide bonds of human complement C1s

C1s, one of the three subcomponents of C1, the first component of the complement system, is a complex serine protease. To determine the disulfide-bonding pattern, fragments of C1s were generated by cleavage with pepsin, thermolysin, or subtilisin. Disulfide bonds have been identified by several methods, for example, direct observation of the phenylthiohydantoin derivative of cystine during Edman degradation of isolated peptides and placement in the known cDNA sequence. All of the 26 half-cystines are linked in disulfide bonds occurring at positions 50-68, 120-132, 128-141, 143-156, 160-187, 219-236, 279-326, 306-339, 344-388, 371-406, 410-534, 580-603, and 613-644. All of the disulfide bonds of the earlier described substructures of C1s, the EGF-homologous part, the two SCR units, and the two domains typical for C1s and C1r are localized within these domains.

Biochemical characterization and tissue distribution of hamster complement C1s

Several mAb (PG11, NG7, and ED4) against hamster complement C1s were obtained. PG11 and NG7 were shown to cross-react with human and rat C1s. By using an immunohistochemical method, we examined localization of C1s in tissues of hamsters and rats. Present results revealed a widespread yet specific staining of hamster C1s which is associated with endoderm-, mesoderm-, and neuroectoderm-derived cells. For example, chondrocyte of hyaline cartilage and surface epithelium of the stomach were strongly positive. Intestinal epithelium, muscle cells, pia mater and epithelium of the choroid plexus of the ventricle, and hepatocytes were also stained. The synthesis of hamster C1s in these organs was confirmed by RNA blot hybridization. Secretion of C1s into the culture medium was revealed by immunoblot analysis in cell lines of hepatocytes, kidney cells, and myoblasts of rat or hamster.