Genetic and Functional Analyses of Membrane Cofactor Protein (CD46) Mutations in Atypical Hemolytic Uremic Syndrome

Clinical Screening

We studied 120 patients with aHUS. Informed consent was obtained. Twelve of these patients had mutations in factor H (20), three had antibodies to factor H (21), and three had mutations in factor I (6). Patients were recruited from pediatric and adult nephrology departments from 2000 to 2005. We describe from this series 11 patients with MCP mutations.

Assays for Complement Components and Regulators

Investigations were performed at the Laboratoire d’Immunologie Biologique of Hôpital Européen Georges Pompidou, Paris, a reference laboratory for investigating the complement system. EDTA plasma samples were obtained. Plasma concentrations of CFH and IF were measured by ELISA, and C4, C3, and factor B were measured by nephelometry (Dade Behring, Paris La Defense, France) (6,20).

Membrane expression of complement regulators was analyzed on granulocytes from patients and control subjects using a FACSCalibur flow cytometer (Becton-Dickinson, Heidelberg, Germany). Cells were stained with saturating concentrations of biotinylated antibodies against MCP (clones GB24 and TRA-2-10) (22) and phycoerythrin-conjugated antibodies against the following: MCP (clone MEM 258; Serotec, Oxford, UK), CD55, and CD59 (clones IA 10 and P282; BD Pharmingen, San Diego, CA). Isotypic mouse IgG1 phycoerythrin (Serotec) or biotinylated MOPC-21 (IgG1; Cappel, West Chester, PA) were used as controls.

We analyzed the MCP expression on granulocytes for 21 healthy donors, 20 patients who were on renal dialysis, and 19 patients with chronic renal failure. MCP expression in those with renal abnormalities was within the range established for the normal donors. The expression of MCP also was assessed by Western blotting of NP-40 solubilized peripheral blood mononuclear cells (PBMC) (11,22).

Genetic Screening

Genomic DNA was isolated from PBMC using the proteinase K/phenol method (23). Coding sequences of the MCP gene were amplified with primers that flanked all 14 exons (Table 1), purified using the Multiscreen plates (Millipore, Molsheim, France), and sequenced with 96 capillary Sequencer 3700 using the dye terminator method (Applied Biosystems, Courtaboeuf, France). For genomic DNA and cDNA sequences, the first nucleotide A of the initiator ATG codon is denoted nucleotide +1. The amino acid number begins at the first amino acid of the mature protein.

Total RNA was extracted from the leukocytes of patients 3 and 5 and isolated using the QIAamp RNA Blood Mini kit (Qiagen, Hilden, Germany). A mixture of oligo (dT) primers and random hexamers were used to synthesize the first strand of cDNA from leukocyte-derived total RNA, according to the manufacturer’s (Promega, Madison, WI) protocols. Oligonucleotide primers for amplification and sequencing of the part of the hMCP cDNA that encompassed exons 1 through 4 were as follows: MCP-1f (5′-TGTTGCTGCTGTACTCCTTCT-3′) and MCP-4r (5′-aggatcagtagcaatttggag-3′). With these primers, amplification of cDNA that contained the wild-type allele is expected to result in a 379-bp fragment.

Mutagenesis, Expression, and Functional Assessment

Substitutions were generated using the QuikChange site-directed mutagenesis kit (Stratagene, La Jolla, CA). MCP isoform BC1 (GenBank accession no. X59405) (18) was cloned into the EcoRI site of plasmid pcDNA3.1+ (Invitrogen, Carlsbad, CA) and sequenced for confirmation (24). CHO K1 cells were transfected using Lipofectamine (Invitrogen). MCP expression was evaluated by ELISA, Western blotting and FACS (25). Ligand binding ELISA and cofactor assays were performed as described previously (22,25). In short, purified C3b and C4b were coated on microtiter wells, and diluted lysates were added in low-ionic-strength buffer. MCP detection was by antibody. For cofactor activity, biotinylated ligands were treated with samples that contained MCP and factor I. SDS-PAGE was used to monitor the generation of cleavage fragments.

Case Reports

All patients were white. Patients 1 through 7 represented sporadic cases, whereas patients 8 through 11 were from two families. Clinical features are summarized in Table 2.

Complement Component Assessment

Complement component profiles are presented in Table 3. In eight (72%) of 11 patients, C3 and factor B levels were in the normal range at the time of investigation. Patient 6 exhibited low C3 and factor B levels, consistent with alternative pathway activation. Her healthy parents had normal plasma levels of C3 and factor B. Patients 5 and 9 had borderline low C3 and factor B levels. Concentration of CFH and IF was in the normal range for all patients.

Molecular Characterization of MCP Mutations

Direct sequencing of the MCP gene included all exons and their flanking regions (Table 4, Figure 1). Five patients (four pedigrees) had a single mutation, and six patients (five pedigrees) had two mutations. Of the latter group, three were homozygous for the same mutation, one had two mutations on the same allele, and two siblings were compound heterozygotes for two mutations. None of the detected mutations was found in 100 normal individuals. In the patients with MCP mutations, mutations were not detected in the 23 exons of the CFH gene and the 13 exons of the IF gene.

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Figure 1.

Genetic studies of membrane cofactor protein (MCP). The approximately 45-kb gene encoding MCP is in the regulators of complement activation gene cluster at 1q32. The 14 exons of the MCP gene are shown as boxes, and the introns are shown as a solid line. The position of each mutation is shown. MCP possesses four complement control protein (CCP) domains, which are encoded by five exons (two exons encode CCP 2). Exons 7, 8, and 9 encode short peptides that contain O-linked sugars that are alternatively spliced. Exon 10 encodes a 13–amino acid juxtamembranous peptide of unknown function. Exons 11 and 12 encode the transmembrane domain and cytoplasmic anchor. Exons 13 and 14 encode the alternatively spliced cytoplasmic tails of 16 and 23 amino acids, respectively.

Several types of mutations were identified. Three patients had nonsense mutations, and three patients had a mutation in the invariant dinucleotide of a splice site. The two compound heterozygous siblings (patients 10 and 11) had both a splice site mutation and a missense mutation in exon 5 (Y155D). Patient 7 as well as her healthy father and brother were heterozygous for an allele that carries the substitutions D151N and Y155D. Other missense mutations in complement control protein (CCP) domain 3 (E145Q and G162R) were identified in two pedigrees (patient 6 and patients 8 and 9).

We identified a heterozygous A to G mutation at position −2 of exon 3 (IVS2 −2A>G). Reverse transcription–PCR using exons 1 and 4 primers of the MCP transcript revealed a 276-bp fragment (Figure 2B). Direct sequencing of this fragment after gel purification revealed exon 3 skipping. This resulted in the deletion of amino acids 62 to 95 with three amino acid changes (G96I, Y97I, and Y98T) and a premature stop codon at amino acid 99. Using a similar approach, we demonstrated that the IVS2 +2T>G mutation also results in abnormal splicing. A 235-bp fragment corresponded to the first 45 bp from exon 2 spliced onto exon 3 (Figure 2A). This resulted in the deletion of 144 bp and 48 amino acids in phase with the wild-type sequence.

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Figure 2.

Analysis of the splice mutations for patients 3 and 5. Reverse transcription–PCR (RT-PCR) products were run on a 2% agarose gel and ethidium bromide stained. (A) Effect of IVS2 +2T>G on exon splicing. RT-PCR from wild-type control (lane 1) generated a single band of 379 bp. Sequencing of this product confirmed this to be exons 2, 3, and 4. RT-PCR from patient 3 with a homozygous IVS2 +2T>G mutation (lane 2) generated a 235-bp band that was sequencing and revealed a 144-bp deletion of the 3′ end of exon 2. (B) Effect of IVS2 −2A>G mutations on exon splicing. Lane 1 again contains a wild-type control RT-PCR product of 379 bp that contains exons 2, 3, and 4. Lane 2 from patient 5 with a heterozygous IVS2 −2A>G mutation gave two RT-PCR products of 379 and 276 bp. These products were sequenced. The 379-bp product was normally spliced exons 2, 3, and 4. The 276-bp product lacked exon 3, confirming exon splicing.

The IVS7 −2A>G splice site mutation was observed only in the setting of the Y155D mutation. Because the latter is not expressed, the protein observed is derived from the other allele bearing the IVS7 −2A>G mutation. On Western blotting of cells from patients 10 and 11, the protein is expressed with an M_r consistent with the wild-type isoforms MCP-C1 or MCP-C2 (26). In these isoforms, exon 8 is spliced out, and this exon also would be predicted to be spliced out in this mutation.

Membrane Expression of MCP in Patients with Mutations

Flow cytometry of PBMC was used to assess the expression of the three membrane complement regulators: Decay accelerating factor (CD55), MCP (CD46), and the inhibitor of the membrane attack complex (CD59) (Table 3). Granulocytes were chosen because this is an easily purified and relatively homogenous cell population. Expression of CD55 and CD59 did not differ between the patients and normal donors.

Figure 3 shows the MCP FACS profile for the 11 patients. No staining was observed on the granulocytes of patients 1 and 2, who were homozygous for the R25X and Y214X mutations, respectively. The binding of two other mAb to these patients’ granulocytes also was tested: GB24, which blocks C3b and C4b binding and interacts with an epitope that requires CCP 3 and 4, and TRA-2-10, which binds CCP 1 and does not block function (22). Neither TRA-2-10 nor GB24 stained these patients’ granulocytes. Patient 3 with homozygous splice site substitution exhibited reduced expression of MCP. Except for patient 6, the heterozygous patients expressed approximately 50% of the normal level of MCP. Patient 6 and her homozygous father expressed high levels of MCP on both their granulocytes (Figure 3) and lymphocytes (data not shown). Western blotting of PBMC confirmed the lack of MCP expression in patients 1 and 2 and markedly reduced expression in patient 3 (data not shown).

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Figure 3.

Analysis of MCP expression on granulocytes of patients with atypical hemolytic uremic syndrome (aHUS). Background binding is indicated by the dotted line. Mean fluorescence intensity (MFI) is given in the upper right hand corner. FACS analysis was performed the day after venipuncture except in the case of patients 6, 8, and 9, whose samples arrived 3 d after venipuncture. To control for this, patient 5 was studied on four consecutive days after venipuncture, and there was no modulation of MCP expression during this trial period (MFI on day 0, 371; day 1, 428; day 2, 450; day 3, 409; day 4, 371).

Functional and Structural Studies in Cell Lines

The four missense mutations are in CCP 3 (Figure 1). CCP 2, 3, and 4 are required for cofactor activity (22). These mutations in CCP 3 were analyzed using transfected CHO cells. The Western blot of these cell lysates demonstrates that MCP that carry mutations E145Q, D151N, and G162R are expressed with the expected M_r (Figure 4). In this process, cell lines are selected on the basis of FACS expression; consequently, they are not necessarily representative of the surface expression profile in vivo. In the case of Y155D, the ratio of precursor to mature protein is increased to approximately 1:1. Normally, the precursor of MCP is approximately 1% of the mature form; therefore, unless the blot is overexposed, it usually is not observed (Figure 4, lane 6). On the basis of structural modeling, the Y155D substitution places a charged amino acid in the hydrophobic core of the protein (22). Retention of the precursor form in the endoplasmic reticulum is indicative of a misfolded protein. Further evidence for a structural abnormality is the apparent aggregates at approximately 180 kD. Precursor forms also are increased in the case of mutant G162R, so this also likely is an aberrantly folded protein.

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Figure 4.

Western blot of CHO cell lysates that were probed with a rabbit polyclonal antibody to MCP. Lane 1 contains the size markers. Lane 7 is CHO cell line not expressing MCP. Lane 6 shows the phenotype of wild-type MCP (BC1 isoform) as expressed by transfected CHO cells. Lanes 2 to 5 are the mutations in wild-type MCP identified in the patients with HUS. MCP that carried mutations E145Q (lane 2), D151N (lane 3), and G162R (lane 5) are expressed with the expected electrophoretic mobility. In the case of Y155D (lane 4) and G162R (lane 5), the ratio of precursor to mature protein is increased, likely indicating a folding problem. These two mutants had decreased surface expression (Table 3, Figure 2) on granulocytes. These cell lines were selected by FACS, so their surface expression, especially in the cases of Y155D and G162R, are not necessarily representative of their in vivo expression pattern. M, mature protein; Pro, precursor protein.

Cell lysates also were used to analyze the functional profile of the mutated proteins (Table 5). Both E145Q and G162R mutations have similar profiles. They are comparable to wild-type MCP relative to their binding to C3b and C4b and cofactor activity for C3b. E145Q, however, has approximately 50% of expected C4b cofactor activity, whereas G162R has no detectable C4b cofactor activity. Because G162R binds C4b normally, this is a mutation that selectively alters protease cleavage of C4b by factor I. Mutations with this profile have been described in CR1 and CD46 (22,27). Although these in vitro data implicate the classical pathway in aHUS pathogenesis, this may not reflect the in vivo setting. Patients 8 and 9, bearing the G162R mutation, have low expression levels (Table 3), consistent with minimal or no surface expression of this protein. This lack of expression will result in a defect in both classical and alternative pathway regulation. E145Q is highly expressed, which could compensate for its reduced function. Further studies on expression, function, and membrane stability of mutants E145Q and G162R are in progress.

The Y155D mutant has no detectable C3b or C4b binding activity and negligible cofactor activity. D151N lacks C4b binding capability and, as would be expected, has no C4b cofactor activity. However, because it was observed only in the setting of the Y155D mutation, its contribution in vivo to deficient complement regulation is not possible to ascertain.