©1996 by The American Society for Biochemistry and Molecular Biology, Inc.
Type II Human Complement C2 Deficiency
ALLELE-SPECIFIC AMINO ACID SUBSTITUTIONS (Ser Phe; Gly Arg) CAUSE IMPAIRED C2 SECRETION (*)

(Received for publication, September 1, 1995; and in revised form, November 6, 1995)

Rick A. Wetsel (1)(§) Judit Kulics Marja-Liisa Lokki Photini Kiepiela Hideto Akama Charles A. C. Johnson Peter Densen (2) Harvey R. Colten (1)

From the  (1)Departments of Pediatrics and Molecular Microbiology, Washington University School of Medicine, St. Louis, Missouri 63110 and the (2)Department of Internal Medicine, Veterans Administration Medical Center, and University of Iowa College of Medicine, Iowa City, Iowa 52242

ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
FOOTNOTES
ACKNOWLEDGEMENTS
REFERENCES

ABSTRACT

Type II complement protein C2 deficiency is characterized by a selective block in C2 secretion. The Type II C2 null allele (C2Q0) is linked to two major histocompatibility haplotypes (MHC) that differ from the MHC of the more common Type I C2 deficiency. To determine the molecular basis of Type II deficiency the two Type II C2Q0 genes were isolated and transfected separately into L-cells. Subsequent molecular biology, biosynthetic, and immunofluorescence studies demonstrated that C2 secretion is impaired in Type II C2 deficiency because of different missense mutations at highly conserved residues in each of the C2Q0 alleles. One is in exon 5 (nucleotide C T; Ser Phe) of the C2Q0 gene linked to the MHC haplotype A11,B35,DRw1,BFS, C4A0B1. The other is in exon 11 (G A; Gly Arg) of the C2Q0 gene linked to the MHC haplotype A2,B5, DRw4,BFS,C4A3B1. Each mutant C2 gene product is retained early in the secretory pathway. These mutants provide models for elucidating the C2 secretory pathway.


INTRODUCTION

The complement system consists of about 30 soluble and membrane proteins that constitute one of several important mediators of host defenses against microbial infection. The complement protein C2 (^1)is a M(r) 100,000 serine proteinase that functions in the classical activation pathway of the complement system. It is encoded by a 20-kb gene of 18 exons that is tightly linked to the homologous 6-kb gene encoding the complement protein factor B(1, 2, 3) . Both genes comprise part of the class III gene cluster (4) located on the short arm of chromosome 6 between the HLA-D and HLA-B loci of the major histocompatibility complex (MHC)(5, 6) .

Deficiency of the second component (C2D) is the most common genetic deficiency of the complement system. In populations of western European origin, the C2 null gene (C2Q0) frequency is about 1%(7, 8) . Molecular heterogeneity in C2 deficiency was recently recognized based on expression of the protein in cell culture of fibroblasts from affected individuals(9) . In Type I C2D, there is no detectable translation of C2-specific mRNA. Multiple C2D families from different geographic regions have been examined, and to date the Type I phenotype in each case results from a 28-bp deletion in the C2Q0 gene that removes 9 bp of the 3`-end of exon 6 and 19 bp of the 5`-end of the adjoining intron(10, 11) . This deletion generates a mature C2 transcript from which exon 6 is deleted, creating a downstream premature stop codon and a failure to synthesize detectable C2 protein (10) . Additionally, all C2Q0 genes examined containing the 28-bp deletion are linked to at least part of the same MHC haplotype/complotype (extended haplotype) A25,B18,C2Q0,BFS,C4A4B2,DRw2 (12, 13) .

In contrast, Type II C2D is characterized by a selective block in C2 secretion (9) and is found in the context of two different MHC extended haplotypes that differ from that associated with Type I C2D, suggesting the possibility of more than one molecular mechanism leading to the secretory block. Accordingly, to examine the molecular genetic basis of Type II C2D, the two C2Q0 genes associated with the Type II extended haplotypes were isolated, transfected separately into L-cells, and the corresponding C2 cDNA sequenced. The data reported here establish that Type II C2D within the HLA haplotype A2,B5,DRw4 complotype C2Q0,BFS,C4A3B1 is due to a single missense mutation (nucleotide G A) leading to a Gly to Arg change at amino acid residue 444. Type II C2D in the context of the HLA haplotype A11,B35,DRw1 complotype C2Q0,BFS,C4A0B1 is due to a different missense mutation (C T) leading to an amino acid change from serine to phenylalanine at residue 189. These single amino acid substitutions result in a marked inhibition of secretion of the respective C2 proteins, although the secretory block is more profound for the Arg mutant.


EXPERIMENTAL PROCEDURES

Type II C2-deficient Family

This family has been described in detail in our earlier report(9) . The nuclear family members who are pertinent to this current study are shown in Fig. 1.


Figure 1: Core pedigree of the C2D type II family. This family has been described previously(9) . Circles denote female family members, and squares male family members. Open symbols represent the normal C2 gene. Black symbols represent the Type I C2Q0 gene. Shaded and hatched symbols represent the Type II C2Q0 genes. The HLA haplotypes and complotypes linked to each C2 gene are indicated at the bottom of the figure.



Primary Fibroblast Cultures

Skin fibroblast cell lines were established from the Type II C2-deficient family members and from normal individuals as described previously(9) . Fibroblasts were maintained at 37 °C in 5% CO(2) in Dulbecco's modified Eagle's medium supplemented with 10% fetal calf serum, 2 mM glutamine, 100 units/ml penicillin, and 100 mg/ml streptomycin.

Isolation and Characterization of C2 Genomic Cosmid Clones

High molecular weight DNA was prepared from peripheral blood leukocytes obtained from individual II.8 (Fig. 1) as described previously(10) . This Type II C2D individual contains both C2 alleles associated with Type II C2 deficiency (Fig. 1). The high molecular weight DNA was partially digested with Sau3A1 and used to prepare a genomic cosmid library as described in detail previously (14) . Approximately 1 million recombinants were plated and screened in duplicate for clones containing the C2 gene by using a nick-translated (15) C2 cDNA as a probe(16) . Of 11 clones that hybridized with the C2 cDNA, five were determined to contain the entire C2 and factor B genes by Southern analysis (17) using cosmid cDNA and P-labeled oligonucleotides that correspond to the 5`- and 3`-ends of exons 1 and 18 of the human C2 and factor B genes, respectively. The five clones containing the entire human C2 gene were then examined for RFLPs, so that the clones could be separated into two groups, with each group corresponding to one of the two different Type II alleles. An EcoRI restriction site in intron 1 was found in two of the clones but was absent in the other three. A clone from each of the two groups was then selected for transfection and biosynthetic studies. The two clones were designated B and C, with C containing the EcoRI restriction site in intron 1. The genomic cosmid clone containing the entire normal C2 gene used in these studies was obtained from a library prepared using DNA isolated from the C2-sufficient sister of the Type I C2-deficient previously reported (9) .

Transfection, Biosynthetic Labeling, and Immunoprecipitations

Murine kidney fibroblast L-cells (American Type Culture Collection, Rockville, MD) were grown to 50% confluence (5 times 10^5 cells/100-mm^2 dish) and transfected with genomic cosmid clones using the CaPO(4) method (18) and 15 mg of cosmid DNA. Precipitates were removed after 5 h, the cells washed twice, and fresh medium was added and incubated 48 h. Cells were then incubated with complete medium containing 400 µg/ml G418 (Geneticin, Life Technologies, Inc.). Transfected cells were subsequently subcloned by limiting dilution. Stable subclones that expressed the greatest amount of C2 intracellular protein and mRNA were selected for further study. Subsequent Southern blot analysis indicated that the stable transfectants selected for study each contained approximately 50 copies of the C2 genomic cosmid DNA. Biosynthetic labeling experiments were performed as described previously(9, 19) .

Isolation of RNA and Northern Blot Analysis

Human fibroblast cells and L-cell transfectants were grown to confluence in 162-cm^2 flasks and stimulated with 100 units/ml human or murine -interferon, respectively, for 24 h prior to RNA harvest to increase C2 gene expression. Approximately 10^8 cells were lysed, and RNA was harvested using the method described by Chirgwin et al.(20) . RNA was quantitated by absorbance at 260 nm. RNA (25 µg) samples were denatured, subjected to electrophoresis in a 1% agarose/formaldehyde gel, transferred to a nylon membrane (Amersham Corp.), processed, and hybridized with a nick-translated human C2 cDNA (16) as described by Virca et al.(21) . After hybridization with the probe for 20 h, the filters were washed three times in 0.2 times SSC containing 1% SDS at 65 °C for 20 min. The blots were then exposed to Hyperfilm (Amersham) with enhancing screens at -70 °C for 24 h.

Construction of cDNA Library and Amplification of C2D Type II cDNA

An oligo(dT)-primed cDNA library was constructed using 10 µg of poly(A) mRNA isolated from L-cells transfected with the C2-containing genomic cosmid clone B. The library was made using the cDNA synthesis method of Gubler and Hoffman (22) and the reagents supplied in a cDNA synthesis kit (Invitrogen, San Diego, CA). After addition of EcoRI-NotI adapters (Invitrogen), the cDNA was ligated to -ZAP II vector arms (Stratagene, La Jolla, CA) and in vitro packaged using the Gigapack Gold packaging extract (Stratagene). Over 10^6 recombinants were prepared, plated, and screened using a random-primed labeled (23) human C2 cDNA(16) . Phagemids were prepared from hybridizing clones as described in the Stratagene -Zap II protocol (Stratagene), and the C2 inserts were characterized by EcoRI and NotI digestion and 1% agarose gel electrophoresis. A clone containing a full-length C2D cDNA insert was subsequently identified, isolated, and sequenced.

The C2 cDNA derived from the other Type II allele was generated by RT-PCR amplification using RNA isolated from L-cells transfected with the genomic cosmid clone, C. Single-stranded cDNA was synthesized from 1 mg of total RNA using the ``cDNA Cycle Kit'' (Invitrogen) and antisense C2 oligonucleotide primers 922 and 034C (see below for sequences). The cDNA was subsequently amplified in four overlapping fragments by the polymerase chain reaction(24) , using the first strand cDNA as template and the following pairs of oligonucleotide primers, which were designed according to the published human C2 cDNA sequence(25) : fragment 1, 395B and 310B; fragment 2, 311D and 034C; fragment 3, 923 and 277; and fragment 4, 922B and 282B. The PCR oligonucleotide sequences are shown below and were constructed with either BamHI and HindIII restriction sites near the 5`- and 3`-ends to facilitate subcloning. The first strand cDNA was initially denatured at 95 °C for 1 min with 50 pmol of each oligonucleotide in a 50-ml solution containing 10 mM Tris, pH 8.3, 50 mM KCl, 1.5 mM MgCl(2), 0.1% gelatin, 300 µM dNTPs, and 0.5 units of KlenTaq 1 DNA polymerase(26) . Following initial denaturation, the cDNA was amplified by melting at 94 °C for 1 min, annealing at 55-64 °C for 2 min, and polymerizing at 72 °C for 2 min using a programmable Hybaid OmniGene thermal cycler (Labnet Corp., Woodbridge, NJ). The amplified cDNA was digested with BamHI and HindIII, purified by low melted agarose extraction using NuSieve GTG-agarose (FMC Bioproducts, Rockland, ME), and subcloned into pBluescript II (Stratagene). Competent Sure cells (Stratagene) were transformed with the ligations, and plasmid DNA was isolated from the recombinants using the alkaline lysis procedure(27) .

Oligonucleotide Synthesis and DNA Sequence Analysis

All primers used for DNA amplification and sequencing were synthesized using an automated DNA synthesizer PCR-Mate, model 391 (Applied Biosystems, Inc., Foster City, CA). The primers used in the reverse transcription and (c)DNA amplification reactions are shown below. Restriction enzyme sites are underlined. All primers used for DNA sequencing were 20-mers identical to the published C2 cDNA sequence (25) . All cDNA and genomic sequencing was performed using double-stranded templates and a model 373A automated DNA sequencer from Applied Biosystems, according to the standard protocol of the Taq DyeDeoxy terminator cycle sequencing kit (Applied Biosystems, Foster City, CA). Oligonucleotides are listed below.

Genomic DNA Amplification and RFLP Analysis

DNA of 431 bp that included exon 11 of the C2 gene was amplified from genomic and cosmid DNA using the polymerase chain reaction (24) and oligonucleotides 923 and 280 (see above for sequences). These oligonucleotides hybridized to nucleotide sequences in exon 10 (923) and 12 (280) of the human C2 gene. Briefly, 1 µg of purified DNA was initially denatured at 95 °C for 1 min with 50 pmol of each oligonucleotide in a 50-ml solution containing 10 mM Tris, pH 8.3, 50 mM KCl, 1.5 mM MgCl(2), 0.1% gelatin, 300 mmol of dNTPs, and 0.5 units of KlenTaq 1 DNA polymerase(26) . Following initial denaturation, the 431-bp fragment was amplified by melting at 94 °C for 1 min, annealing at 58 °C for 2 min, and polymerizing at 72 °C for 2 min using a programmable Hybaid OmniGene thermal cycler (Labnet Corp). After 30 cycles, the amplified DNA was phenol-extracted and ethanol-precipitated. The DNA was resuspended in 50 µl of 0.1 mM Tris, pH 8.0. Twenty-five microliters of each sample was digested with 50 units of PstI using conditions recommended by the manufacturer (Promega). Undigested and digested DNA samples were subjected to 2% agarose gel electrophoresis. The DNA fragments were subsequently visualized by ethidium bromide staining.

Indirect Immunofluorescence

Indirect immunofluorescence of transfected cells was performed as described (28) with minor modifications. L-cells transfected with normal and type II C2-containing genomic cosmid clones and untransfected cells were transferred onto glass coverslips. Cells were incubated at 37 °C for 48 h, rinsed in cold water for 5 min, and permeabilized with 0.2% Triton X-100 in PBS (5 mM phosphate, 150 mM NaCl, pH 7.4) for 20 min at room temperature. The cells were incubated overnight at 37 °C with goat anti-human C2 antibody (IgG fraction, Binding Site, Birmingham, United Kingdom), or purified goat IgG as a negative control (Pierce) (0.8 mg/ml, each). Cells were washed three times with PBS containing 1% Triton X-100, 0.2% Tween 20, and incubated with biotin-conjugated rabbit anti-goat IgG antibody (Pierce) (diluted 1:5000 in PBS containing 3% bovine serum albumin) for 1 h at room temperature. This incubation was followed by an incubation with avidin-fluorescein isothiocyanate (Boehringer Mannheim) (diluted 1:300 in PBS with 3% bovine serum albumin) for 1 h at room temperature, then washed as above. The coverslips were immersed in a 0.1% solution of Evans Blue at room temperature for 20 min as a counterstain. The coverslips were washed gently for 5 min, rinsed in distilled water, dried thoroughly, and mounted on glass slides with 50% glycerol in PBS. 1,4-Diazabicyclo(2.2.2)octane (Sigma) (2.5%) was included as an anti-fade reagent in the mounting medium.


RESULTS

Pedigree of Type II C2D Family

A diagram of the nuclear family with Type II C2 deficiency is shown in Fig. 1. The solid symbol, representing the Type I C2Q0 gene, is maternally inherited by two offspring (III-8, III-9) who are compound Type I/Type II C2-deficient. The father (II-8) is homozygous Type II C2D and contains both Type II C2Q0 genes in association with the MHC extended haplotypes A2,B5,DRw4,BFS,C2Q0,C4A3B1 and A11,B35,DRw1,BFS,C2Q0,C4A0B1. Serum C2 levels were 760 ng/ml (4% of normal) and 57 ng/ml (0.2% of normal) for the Type II father (II-8) and propositus (III-9), respectively.

Biosynthesis of C2 and Factor B

A representative study of C2 and factor B biosynthesis in primary culture of fibroblasts from a normal and the Type II C2-deficient father with both Type II C2Q0 genes is shown in Fig. 2. C2 polypeptides of M(r) 84,000, 79,000, and 70,000 were detected in the cell lysates and C2 protein of M(r) 95,000-100,000 in culture medium of [S]methionine, pulse-labeled normal fibroblasts (Fig. 2, top panel, left two lanes), confirming previous studies of C2 synthesis and secretion(29) . The same three intracellular C2 polypeptides were detected in the fibroblasts of the Type II C2-deficient father, but in markedly increased amounts (especially the M(r) 84,000 and 70,000 forms), and a small amount of mature C2 protein of approximately normal size was detected in the extracellular medium (Fig. 2, middle two lanes, top panel).


Figure 2: Synthesis of C2 and factor B by fibroblasts and transfected L-cell. Shown are autoradiograms of SDS-polyacrylamide gels (7.5% in reducing conditions) of methionine-labeled C2 and factor B immunoprecipitated from intracellular lysates (I) and culture media (X) as described under ``Experimental Procedures.'' The normal lanes are from skin fibroblasts of a homozygous C2-sufficient female (A-III-2 in (9) ). The Type II lanes are from skin fibroblasts of the homozygous C2D Type II father (II.8 in Fig. 1). The clone B lanes are from L-cells transfected with a cosmid genomic clone containing complete C2 and factor B genes corresponding to one of the Type II C2D alleles. L-cells transfected with clone C gave the same results as shown here for clone B (see text for details). Arrows indicate the major C2 and factor B intracellular and extracellular polypeptides identified in previous studies(29) .



To examine C2 biosynthesis from each of the C2D Type II genes, murine L cells were separately transfected with cosmid clones bearing the entire factor B and C2 genes corresponding to normal and each of the Type II C2Q0 genes (described in detail under ``Experimental Procedures''). The latter were separable by the presence of an EcoRI RFLP in intron 1 of the C2 gene. The M(r) 84,000 intracellular C2 protein was abundant in lysates of L cells transfected with cosmid clones derived from each of the Type II C2Q0 genes, but as in the primary fibroblasts only a trace amount of C2 protein was present extracellularly (Fig. 2, right two lanes, top panel). The apparent defect in secretion of C2 in Type II C2D fibroblasts and the transfectants is selective because factor B is synthesized and secreted normally in the deficient fibroblasts and the transfectants (Fig. 2, bottom panel).

Kinetics of C2 Secretion

To ascertain whether the limited recovery of C2 protein in extracellular medium was due to a decreased capacity of Type II C2D fibroblasts and the transfectants to secrete C2, a pulse-chase experiment was performed. In agreement with earlier reports(29) , the results shown in Fig. 3indicate that the M(r) 84,000 C2 protein in normal fibroblasts was secreted with a half-time of about 1 h and that the M(r) 79,000 and 70,000 C2 proteins remain cell-associated (Fig. 3, top panel). In contrast, the half-time for disappearance of the M(r) 84,000 C2 protein in the Type II C2D fibroblasts was approximately 2-4 h, and only a trace amount of C2 was detected in culture medium at 8 h (Fig. 3, bottom panel). Fig. 4shows data from pulse-chase studies of L-cells transfected with cosmid clones containing the normal and each Type II C2Q0 gene. The biosynthesis of C2 in the normal and Type II transfected cells was similar to that for the corresponding primary cells. For example, in L-cells transfected with the normal clone, the disappearance of the M(r) 84,000 intracellular C2 protein and appearance of the extracellular protein displayed kinetics similar to the primary cells. Additionally, the C2D Type II transfectants showed the same prolonged half-time of disappearance of intracellular C2 protein (half-time 2-4 h) as did the primary cells. In these experiments, the C2 in the extracellular medium was occasionally cleaved to C2a and C2b, shown by the C2a fragment of M(r) 74,000 in the Normal and Clone C panels in Fig. 4. Factor B secretion kinetics (half-time approximate 60 min) were identical in all cell types and similar to previous reports (data not shown). Collectively, the biosynthetic experiments indicate that Type II deficiency is caused by mutations within the Type II C2 genes, since transfected cells duplicate the C2D phenotype of primary Type II fibroblasts.


Figure 3: Rate of C2 secretion from normal and C2D Type II skin fibroblasts. Fibroblasts were metabolically labeled, washed, and incubated in medium containing excess unlabeled methionine for the times indicated as described under ``Experimental Procedures.'' At the indicated time points, C2 was immunoprecipitated from intracellular lysates and extracellular medium and subjected to SDS-polyacrylamide gel electrophoresis (7.5% in reducing conditions). Skin fibroblasts were from the normal and homozygous C2D Type II individuals studied in Fig. 2. Shown are autoradiograms from 72-h exposures at -70 °C with enhancing screens. Arrows indicate the major C2 intracellular and extracelullar polypeptides.




Figure 4: Rate of C2 secretion from L-cells transfected with cosmid clones containing normal C2 or Type II C2Q0 genes. L-cells that were transfected with cosmid clones containing the normal and Type II C2Q0 genes were metabolically labeled, washed, and incubated in medium containing excess unlabeled methionine for the times indicated as described under ``Experimental Procedures.'' At the indicated time points, C2 was immunoprecipitated from intracellular lysates (lanes on the left side of each panel) and extracellular medium (lanes on the right side of each panel) and subjected to SDS-polyacrylamide gel electrophoresis (7.5% in reducing conditions). Clones were isolated from cosmid libraries constructed using DNA from the normal and homozygous C2D Type II individuals studied in Fig. 2and Fig. 3(see text for details). Shown are autoradiograms from 48-h exposures at -70 °C with enhancing screens. Arrows indicate the C2 intracellular and extracellular polypeptides.



Immunofluorescence of L-cells Transfected with C2 Genomic Cosmid Clones

Immunofluorescence studies of the transfected L-cells were performed as outlined under ``Experimental Procedures.'' Cells transfected with the normal C2 genomic cosmid clone showed a diffuse pattern of fluorescence throughout the cytosol of the cell (Fig. 5, panel a). In contrast, only perinuclear immunofluorescence was observed in L-cells transfected with either of the C2D Type II genomic cosmid clones (Fig. 5, panels c and d), suggesting distribution of C2 protein in the Golgi and/or rough endoplasmic reticulum of the C2D Type II transfectants. In addition, the overall fluorescence signal was approximately 10 times more intense in the C2D Type II transfectants compared with the normal transfectants (note exposure times in Fig. 5). The increased fluorescence observed in the C2D Type II transfectants is in accord with the immunoprecipitation data, indicating intracellular accumulation of the C2D Type II protein. The negative controls of untransfected L-cells (Fig. 5, panel b) and L-cells mock-transfected with vector alone (data not shown) showed no background immunofluorescence.


Figure 5: Indirect immunofluorescence microscopy of L-cells transfected with normal C2 and Type II C2Q0 genes. Shown are photomicrographs (magnification, times1000 of L-cells transfected with cosmid clones containing the normal (panel a) and Type II C2Q0 genes. L-cells transfected with Type II clones B and C are shown in panels c and d, respectively. Untransfected L-cell controls are shown in panel b. The photomicrographs in panels a and b were obtained from a 10-s exposure and those in panels c and d were obtained from a 1-s exposure. C2-specific immunofluorescence was performed as outlined under ``Experimental Procedures.''



Northern Blot Analysis of C2 mRNA in C2D Type II Primary Fibroblasts and Transfected L-cells

To compare the mRNA transcribed from the normal and C2D Type II genes, RNA was isolated from primary fibroblasts and from L-cells transfected with normal and C2D Type II cosmid clones and subjected to Northern blot analysis as described under ``Experimental Procedures.'' The C2-specific mRNA detected in the C2D Type II skin fibroblast cells (Fig. 6, lane 1) was similar in size (2.7 kb) and quantity to the C2 mRNA detected in normal skin fibroblast cells (data not shown). In addition, the L-cells transfected with normal (Fig. 6, lane 2) and both C2D Type II genomic cosmid clones (Fig. 6, lanes 3 and 4) expressed a major C2 transcript of identical size (2.7 kb) as that seen in the primary fibroblasts. The transfectants contained 20-100-fold more C2 mRNA compared to the primary fibroblast cells. This increased C2 expression was expected, since the transfected L-cells each contained approximately 50 copies of C2 genomic DNA as determined by Southern blot analysis (described under ``Experimental Procedures''). L-cells transfected with normal C2 and C2D Type II clones also expressed a less abundant smaller C2 transcript of 2.2 kb. Since this 2.2-kb transcript was seen in both normal and C2D transfectants but not in non-transfected L-cells (Fig. 6, lane 5), it is probably derived from aberrant splicing of the human C2 primary transcript by the mouse L-cells.


Figure 6: Detection of C2 RNA in C2D Type II fibroblasts and transfected L-cells by Northern blot analysis. Twenty-five micrograms of total RNA isolated from fibroblasts and transfected L-cells were subjected to Northern blot analysis as described under ``Experimental Procedures.'' A full-length P-radiolabeled human C2 cDNA was used as a hybridization probe to detect C2-specific RNA. Shown is an autoradiogram that was developed after a 24-h exposure at -70 °C with an enhancing screen. The lanes correspond to RNA isolated from the following cultures: lane 1, skin fibroblasts isolated from the C2D homozygous Type II individual II.8 in Fig. 1; lane 2, L-cells transfected with a cosmid clone containing a normal C2 gene; lane 3, L-cells transfected with cosmid clone B that contains one of the Type II C2Q0 genes; lane 4, L-cells transfected with cosmid clone C that contains the other Type II C2Q0 gene; lane 5, untransfected L-cells. The quantities of RNA loaded in each lane were comparable as judged by ethidium staining (data not shown). The normal size (approximately 2.7 kb) C2 mRNA is indicated by the arrow on the left. The mobilities of the 28 and 18 S ribosomal RNA are indicated by the arrows on the right.



Sequence Analysis of the C2D Type II cDNA

To examine the C2 primary amino acid structure for mutations that would account for the impaired C2-specific secretion in C2D Type II cells, C2 cDNA were generated and sequenced using RNA from the L-cell transfectants. A full-length C2 cDNA clone was isolated from a cDNA library constructed using poly(A) mRNA harvested from L-cells transfected with cosmid clone B as described under ``Experimental Procedures.'' The nucleotide sequence of this cDNA was identical to published human C2 sequences (16, 25, 30) except for a single base change (G A) at nucleotide 1330. This substitution predicts a change in the amino acid at residue 444 from glycine to arginine and generates a PstI restriction site in exon 11 of the mutant C2Q0 gene (Fig. 7). The presence of this nucleotide substitution was confirmed by sequence analysis of PCR fragments generated from genomic DNA isolated from primary fibroblast cultures and peripheral white blood cells of the C2D Type II propositus (Fig. 1, III.9) and his father (Fig. 1, II.8).


Figure 7: Location of missense mutations in the Type II C2Q0 genes. Shown at the top of this figure is the exon/intron organization of the human C2 gene(3) . Exons are depicted by the numbered boxes with untranslated sequences indicated by shorter boxes. Exons encoding short consensus repeats (SCRs) are indicated by stippled boxes, those encoding the von Willebrand factor type A-like domain by striped boxes, and those encoding the serine esterase domain by solid boxes. The SINE-R.C2 retroposon is represented by the horizontal open box in intron 3. The position of the C1 s cleavage site is shown by an arrow. The exon 5 missense mutation (C T; Ser Phe) and proximal nucleotide and amino acid sequences are shown on the left. The exon 11 missense mutation (G A; Gly Arg) and proximal nucleotide and amino acid sequences are shown on the right. The B and C boxes depict the C2D Type II cosmid clone that was used to determine the corresponding missense mutation. No mutations, other than the missense mutations, are present in the cDNA derived from the B and C clones.



The full-length C2 cDNA sequence corresponding to the other C2D Type II allele was delineated from overlapping subcloned cDNA fragments generated by RT-PCR using RNA isolated from the L-cells transfected with cosmid clone C (see ``Experimental Procedures''). The nucleotide sequence of this cDNA was also identical to published human C2 sequences except for a single base change. In this case, a C T substitution occurs at nucleotide position 566, resulting in a predicted serine to phenylalanine amino acid change at residue position 189, which is located in exon 5 of the C2Q0 gene (Fig. 7). The presence of this nucleotide substitution was confirmed by sequence analysis of PCR fragments generated from genomic DNA isolated from the father of the propositus. These results together with the biosynthetic data demonstrate that the T and A nucleotide substitutions in exons 5 and 11 of the Type II C2Q0 genes are missense mutations that ultimately result in the synthesis of mutant full-length C2 precursor proteins. Because of each amino acid substitution (either Phe or Gly), the C2 mutant precursor is retarded in transit through the normal C2 secretory pathway.

Determination of Type II C2Q0/HLA Linkage by RFLP Analysis

To determine the HLA haplotype linkage for each of the Type II C2Q0 genes, RFLP analysis was performed by PstI digestion of PCR generated C2 genomic DNA fragments of 431 bp that included exon 11 as described in the Experimental Procedures. The 431-bp genomic fragments were amplified using DNA isolated from the C2D Type II cosmid clones B and C and from genomic DNA isolated from from the mother, father, and propositus of the C2D Type II family (Fig. 8). As described above, the exon 11 missense mutation A found in clone B generates a PstI RFLP. Therefore, as expected, digestion of the 431-bp fragment from cosmid clone B yields three bands of predicted size, one of 37 bp generated by a normal PstI site contained in exon 10, and bands of 217 and 177 bp generated by the PstI site created by the A missense mutation (Fig. 8). Since neither the normal C2 gene nor the Type I C2Q0 gene contain the exon 11 missense mutation, digests of the PCR fragments from clone C and the heterozygous C2D Type I mother yielded as expected only the 37- and 394-bp fragments generated by the exon 10 PstI site (Fig. 8). Additionally, DNA from the homozygous C2D father who contains both Type II C2Q0 genes yields all four bands (394, 217, 177, and 37 bp), as would be predicted for someone containing the exon 11 missense mutation in one C2 allele. PstI digestion of DNA from the homozygous C2D propositus who contains a Type I and a Type II C2Q0 gene also yielded these four bands, thereby demonstrating that his Type II C2Q0 gene contains the exon 11 missense mutation. Moreover, this finding, together with previous tissue typing data(9) , indicates that the extended haplotype linked to the Type II C2Q0 gene containing the exon 11 missense mutation is A2,B5,DRw4,BFS,C4A3B1 and that linked to the Type II C2Q0 gene containing the exon 5 missense mutation is A11,B35,DRw1,BFS,C4A0B1.


Figure 8: Determination of HLA haplotype linkage by RFLP analysis. Shown is an ethidium-stained 2% agarose gel in which PCR generated genomic DNA was subjected to PstI RFLP analysis and electrophoresis as described under ``Experimental Procedures.'' The DNA samples used to amplify the PCR products are indicated by the square boxes above the corresponding lanes. The cosmid DNA was purified from the Type II C2D genomic clones B and C. Genomic DNA was purified from peripheral blood leukocytes of the indicated Type II C2D family members (see Fig. 1for family pedigree). DNA samples not digested(-) or digested (+) with PstI are indicated at the bottom of the agarose gel. The arrows indicate the four DNA bands of interest (see text for details). The DNA size markers used are X174 cut with HaeIII. The strategy employed in the RFLP analysis is shown at the bottom of this figure. Oligonucleotides used in the PCR amplifications are indicated by arrows above exons 10 and 12. Shown are the natural PstI site in exon 10 and the PstI polymorphism resulting from the exon 11 missense mutation (indicated by an asterisk). DNA fragments predicted from the RFLP strategy are drawn as horizontal lines. The numbers indicate the predicted size (bp) of each fragment.




DISCUSSION

Type II C2 deficiency is characterized by a selective block in C2 secretion and has been found in the context of two different MHC haplotypes(9) . Using L-cells transfected with the two separate Type II-associated C2Q0 genes, it is demonstrated here that C2 secretion is impaired in Type II cells because of two distinct C2Q0 allele-specific missense mutations that result in critical amino acid substitutions in the C2 protein structure. One missense mutation is in exon 11 (G A) in the Type II C2Q0 gene linked to the HLA haplotype A2,B5,DRw4, complotype BFS,C4A3B1. This mutation results in a Gly Arg substitution. The other missense mutation is in exon 5 (C T) in the type II C2Q0 gene linked to the HLA haplotype A11,B35,DRw1, complotype BFS,C4A0B1 and results in a Ser Phe substitution.

During the past decade, the molecular genetic basis of numerous protein deficiencies has been determined. The mutations that cause these deficiencies are of several different types and include various nonsense mutations, splice site mutations, transcriptional promoter sequence mutations, and missense mutations. As in the case of Type II C2 deficiency, recent studies have demonstrated that several protein deficiencies result from missense mutations that cause critical amino acid changes, which directly impair secretion of the affected protein. For example, secretory defects due to single amino acid substitutions have been reported to cause protein deficiencies of Type IIA von Willebrand factor(31) , high molecular weight kininogen(32) , alpha(1)-antichymotrypsin(33) , human hepatic lipase(34) , protein C(35) , murine I light chain(36) , alpha(1)-antitrypsin(37) , lysosomal alpha-glucosidase(38) , and complement component C3(39) . In some of these cases, the molecular/cellular basis of the secretory defect has been examined. Some missense mutations appear to impair secretion by disrupting critical structural domains that cause misfolding of the protein. In other cases, missense mutations do not cause large structural changes but instead alter important recognition determinants in the protein required for efficient processing, transport, and secretion. An example of the former case occurs in PiZZ alpha(1)-antitrypsin deficiency in which a single amino acid substitution, lysine for glutamate 342, results in the synthesis of an improperly folded protein that cannot readily be transported through the secretory pathway. The mutant PiZZ alpha(1)-antitrypsin molecule instead remains bound in the lumen of the endoplasmic reticulum, where it ultimately undergoes degradation. In contrast, a single serine for phenylalanine 62 substitution in a conserved region of the variable domain of I light chain does not induce obvious structural changes. The mutant I light chain still assembles with the heavy chain forming a functional antigen-binding antibody and is still recognized by several polyclonal and monoclonal anti- antibodies(36) . However, the mutant I light chain is not secreted but is arrested in the endoplasmic reticulum in association with two lumenal endoplasmic reticulum stress/chaperon proteins, BiP/GRP78 and GRP94(40, 41) . These chaperon proteins are involved in the normal folding of light chains by transient interactions; however, I mutants appear to bind BiP/GRP78 and GRP94 more avidly, thereby inhibiting the normal processing and secretion of the mutant light chain.

The molecular and cellular mechanisms by which the Type II missense mutations cause impaired C2 secretion are currently not known. The three-dimensional structure of C2 has not been determined; it is therefore difficult to predict what these two mutations might do to the overall structure of the C2 molecule. However, comparison of the murine and human C2 sequences indicate that both mutations are located in highly conserved regions of the C2 molecule, suggesting the importance of these regions in the normal expression of a functional C2 protein. For example, there is 74% overall amino sequence identity between murine and human C2. In contrast, the phylogenetic identity proximal to the exon 5 and 11 missense mutations is much greater, with 100% identity observed in the 19 and 16 amino acids immediately surrounding the Phe and Arg mutations in exon 5 and 11, respectively,(2, 3) . Moreover, exon 11, that encodes part of the C2 serine protease domain, is one of the most conserved exons in the C2 gene, with 94% sequence identity shared between the human and murine amino acid sequences. In addition to its location in a highly conserved region, the exon 11 Arg mutation is only three amino acids upstream of a possible N-linked glycosylation site at Asn. The charge change resulting from the Arg substitution could disrupt the overall structure of this conserved region or inhibit proper glycosylation of Asn. Either of these possibilities could affect interactions of the mutant C2 protein with resident endoplasmic reticulum proteins and cause retention in this compartment. The substitution of the small polar Ser with a large aromatic nonpolar Phe residue in exon 5 could also disrupt structural features important in the secretion of C2, especially since the substitution occurs between two aromatic Tyr residues (Fig. 7).

Hereditary C2 deficiency is the most common complement deficiency in individuals of western European descent, with approximately 1 person in 10,000 being homozygous C2-deficient. More than half of homozygous C2D individuals have rheumatological disorders, including systemic lupus erythematosus(7, 42) . In addition, many are predisposed to recurrent pyogenic bacterial infections(43) . Current data indicate that the majority (93%) of C2 deficiency (C2Q0) genes contain the Type I mutation (28-bp partial gene deletion), and almost all Type I C2Q0 genes are linked to the extended haplotype HLA-A25,B18,BFS,C4A4B2,DRw2 (10, 11, 44) . All remaining Type I C2Q0 genes are associated with parts of this haplotype, suggesting that the 28-bp deletion originated 600-1300 years ago with the complete haplotype(12) . Recent reports have indicated that there is no apparent correlation with these different clinical manifestations and variations in the Type I C2Q0-associated HLA extended haplotypes(11, 45) .

In contrast to Type I C2Q0 genes, it has been assumed that Type II C2Q0 genes are rare and comprise no more than the remaining 7% of C2D Caucasian individuals who do not contain the Type I mutation(10) . However, the possibility that the abundance of Type II C2Q0 genes has been underestimated as the result of ascertainment bias should be considered. For example, the majority of C2D families have been discovered by the manifestation of one of the associated clinical problems in a homozygous Type I C2D family member. Since Type II C2D individuals contain some serum C2, it is possible that Type II homozygous C2D individuals do not develop clinical problems as readily as Type I homozygous individuals who lack detectable C2 in their serum. Now that the molecular genetic mutations causing Type II C2D have been delineated, it is possible to examine individuals who contain all or part of the two Type II C2D-associated MHC haplotypes for the Type II missense mutations. Such an investigation should yield a more definite picture regarding the abundance of Type II C2Q0 genes and clinical manifestations associated with Type II C2D. Moreover, continued study of Type II C2D cells will reveal additional insights regarding folding, processing, and secretion of C2 as well as other secretory proteins in general.


FOOTNOTES

*
This work was supported in part by United States Public Health Service Grants AI25011 (to R. A. W.), HD17461 (to H. R. C.), and AI24739 (to H. R. C.), a merit review award from the Department of Veteran Affairs (to P. D.), and a grant-in-aid from the American Heart Association (to P. D.). The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore by hereby marked ``advertisement'' in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

§
Recipient of Research Career Development Award AI00919 from the National Institutes of Health. To whom correspondence should be addressed: Dept. of Pediatrics, Box 8116, Washington University School of Medicine, One Children's Pl., St. Louis, MO 63110. Tel.: 314-454-2285; Fax: 314-454-2476.

(^1)
The abbreviations used are: C2, the second complement component; bp, base pair(s); C2D, C2-deficient; C2Q0, C2 null allele; HLA, human leukocyte antigen; kb, kilobase (s); MHC, major histocompatibility complex; PBS, phosphate-buffered saline; PCR, polymerase chain reaction; RFLP, restriction fragment length polymorphism; RT-PCR, reverse transcriptase polymerase chain reaction.


ACKNOWLEDGEMENTS

We thank Robert K. Hurford, Jr. and Martin Mohren for assistance in genomic library construction and clone isolations, Dr. Lori Singer for cloning some of the stable C2 transfectants, Joie Haviland and Michelle Van Hee for expert technical assistance, and Barbara Dickeson for preparation of the manuscript.


REFERENCES

  1. Alper, C. A. (1976) J. Exp. Med. 144, 1111-1115 [Abstract]
  2. Ishikawa, N., Nonaka, M., Wetsel, R. A., and Colten, H. R. (1990) J. Biol. Chem. 265, 19040-19046 [Abstract/Free Full Text]
  3. Ishii, Y., Zhu, Z.-B., Macon, K. J., and Volanakis, J. E. (1993) J. Immunol. 151, 170-174 [Abstract/Free Full Text]
  4. Carroll, M. C., Campbell, R. D., Bentley, D. R., and Porter, R. R. (1984) Nature 307, 237-241 [Medline] [Order article via Infotrieve]
  5. Fu, S. M., Kunkel, H. G., Brusman, H. P., Allen, F. H., Jr., and Fotino, M. (1974) J. Exp. Med. 140, 1108-1111 [Medline] [Order article via Infotrieve]
  6. Raum, D. D., Awdeh, Z. L., Glass, D., Yunis, E., and Alper, C. A. (1981) Immunogenetics 12, 473-483 [Medline] [Order article via Infotrieve]
  7. Glass, D., Raum, J. D., Gibson, D., Stillman, J. S., and Schur, P. (1976) J. Clin. Invest. 58, 853-861 [Medline] [Order article via Infotrieve]
  8. Rynes, R. I., Britten, A. F., and Pickering, R. J. (1982) Ann. Rheum. Dis. 41, 93-96 [Abstract]
  9. Johnson, C. A., Densen, P., Wetsel, R. A., Cole, F. S., Goeken, N. E., and Colten, H. R. (1992) N. Engl. J. Med. 326, 871-874 [Medline] [Order article via Infotrieve]
  10. Johnson, C. A., Densen, P., Hurford, R., Jr., Colten, H. R., and Wetsel, R. A. (1992) J. Biol. Chem. 267, 9347-9353 [Abstract/Free Full Text]
  11. Truedsson, L., Alper, C. A., Awdeh, Z. L., Johansen, P., Sjoholm, A. G., and Sturfelt, G. (1993) J. Immunol. 151, 5856-5863 [Abstract/Free Full Text]
  12. Alper, C. A. (1987) Immunol. Lett. 14, 175-181
  13. Awdeh, Z. L., Raum, D. D., Glass, D., Agnello, V., Schur, P. H., Johnston, R. B., Jr., Gelfand, E. W., Ballow, M., Yunis, E., and Alper, C. A. (1981) J. Clin. Invest. 67, 581-583 [Medline] [Order article via Infotrieve]
  14. Wetsel, R. A., Fleischer, D. T., and Haviland, D. L. (1990) J. Biol. Chem. 265, 2435-2440 [Abstract/Free Full Text]
  15. Rigby, P. W., Dieckmann, M., Rhodes, C., and Berg, P. (1977) J. Mol. Biol. 113, 237-251 [Medline] [Order article via Infotrieve]
  16. Woods, D. E., Edge, M. D., and Colten, H. R. (1984) J. Clin. Invest. 74, 634-638 [Medline] [Order article via Infotrieve]
  17. Reed, K. C., and Mann, D. A. (1985) Nucleic Acids Res. 13, 7207-7221 [Abstract]
  18. Chen, C., and Okayama, H. (1988) BioTechniques 6, 632-638 [Medline] [Order article via Infotrieve]
  19. Perlmutter, D. H., Colten, H. R., Grossberger, D., Strominger, J., Seidman, J. G., and Chaplin, D. D. (1985) J. Clin. Invest. 76, 1449-1454 [Medline] [Order article via Infotrieve]
  20. Chirgwin, J. M., Przybyla, A. E., MacDonald, R. J., and Rutter, W. J. (1979) Biochemistry 18, 5294-5299 [Medline] [Order article via Infotrieve]
  21. Virca, G. D., Northemann, W., Shiels, B. R., Widera, G., and Broome, S. (1990) BioTechniques 8, 370-371 [Medline] [Order article via Infotrieve]
  22. Gubler, U., and Hoffman, B. J. (1983) Gene (Amst.) 25, 263-269
  23. Feinberg, A. P., and Vogelstein, B. (1983) Anal. Biochem. 132, 6-13 [Medline] [Order article via Infotrieve]
  24. Saiki, R. K., Gelfand, D. H., Stoffel, S., Scharf, S. J., Higuchi, R., Horn, G. T., Mullis, K. B., and Erlich, H. A. (1988) Science 239, 487-491 [Medline] [Order article via Infotrieve]
  25. Horiuchi, T., Macon, K. J., Kidd, V. J., and Volanakis, J. E. (1989) J. Immunol. 142, 2105-2111 [Abstract/Free Full Text]
  26. Barnes, W. M. (1992) Gene (Amst.) 112, 29-35
  27. Birnboim, H. C. (1983) Methods Enzymol. 100, 243-255
  28. Harlow, E., and Lane, D. (1988) Antibodies: A Laboratory Manual , pp. 359-420, Cold Spring Harbor Laboratory, Cold Spring Harbor, NY
  29. Perlmutter, D. H., Cole, F. S., Goldberger, G., and Colten, H. R. (1984) J. Biol. Chem. 259, 10380-10385 [Abstract/Free Full Text]
  30. Bentley, D. R. (1986) Biochem. J. 239, 339-345 [Medline] [Order article via Infotrieve]
  31. Lyons, S. E., Bruck, M. E., Bowie, E. J., and Ginsburg, D. (1992) J. Biol. Chem. 267, 4424-4430 [Abstract/Free Full Text]
  32. Hayashi, I., Hoshiko, S., Makabe, O., and Oh-ishi, S. (1993) J. Biol. Chem. 268, 17219-17224 [Abstract/Free Full Text]
  33. Faber, J. P., Poller, W., Olek, K., Baumann, U., Carlson, J., Lindmark, B., and Eriksson, S. (1993) J. Hepatol. 18, 313-321 [Medline] [Order article via Infotrieve]
  34. Durstenfeld, A., Ben-Zeev, O., Reue, K., Stahnke, G., and Doolittle, M. H. (1994) Arterioscler. Thromb. 14, 381-385 [Abstract]
  35. Miyata, T., Zheng, Y. Z., Sakata, T., Tsushima, N., and Kato, H. (1994) Thromb. Haemostasis 71, 32-37 [Medline] [Order article via Infotrieve]
  36. Dul, J. L., and Argon, Y. (1990) Proc. Natl. Acad. Sci. U. S. A. 87, 8135-8139
  37. Perlmutter, D. H. (1993) in Progress in Liver Disease (Ockner, R. K., and Boyer, J., eds) Vol. IX, pp. 139-165, W. B. Saunders, Philadelphia
  38. Hermans, M. M., de Graaff, E., Kroos, M. A., Wisselaar, H. A., Willemsen, R., Oostra, B. A., and Reuser, A. J. (1993) Biochem. J. 289, 687-693 [Medline] [Order article via Infotrieve]
  39. Singer, L., Whitehead, W. T., Akama, H., Katz, Y., Fishelson, Z., and Wetsel, R. A. (1994) J. Biol. Chem. 269, 28494-28499 [Abstract/Free Full Text]
  40. Melnick, J., Aviel, S., and Argon, Y. (1992) J. Biol. Chem. 267, 21303-21306 [Abstract/Free Full Text]
  41. Melnick, J., Dul, J. L., and Argon, Y. (1994) Nature 370, 373-375 [CrossRef][Medline] [Order article via Infotrieve]
  42. Hartung, K., Fontana, A., Klar, M., Krippner, H., Jorgens, K., Lang, B., Peter, H. H., Pichler, W. J., Schendel, D., and Robin-Winn, M. (1989) Rheumatol. Int. 9, 13-18 [Medline] [Order article via Infotrieve]
  43. Figueroa, J. E., and Densen, P. (1991) Clin. Microbiol. Rev. 4, 359-395 [Medline] [Order article via Infotrieve]
  44. Sullivan, K. E., Petri, M. A., Schmeckpeper, B. J., McLean, R. H., and Winkelstein, J. A. (1994) J. Rheumatol. 21, 1128-1133 [Medline] [Order article via Infotrieve]
  45. Truedsson, L., Sturfelt, G., and Nived, O. (1993) Lupus 2, 325-327 [Medline] [Order article via Infotrieve]

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