|Home | About | Journals | Submit | Contact Us | Français|
Autoantibodies to the human muscarinic acetylcholine receptor of the M3 type (hmAchR M3) have been suggested to play an etiopathogenic role in Sjögren's syndrome. Primary biliary cirrhosis (PBC) often is associated with this syndrome. Therefore, we studied the co-presence of hmAchR M3 autoantibodies in patients with PBC.
Frequency of hmAchR M3 autoantibodies was assessed by Western blotting analysis as well as by an ELISA using a 25-mer peptide of the 2nd extracellular loop of hmAchR M3. Co-localization of hmAchR M3/PBC-specific autoantibodies was studied by confocal laser scanning microscopy. Finally, sera from patients with PBC as well as from healthy controls were tested.
Western blotting analysis as well as results from ELISA testing revealed a significantly enhanced IgG reactivity in PBC patients in contrast to healthy controls. Co-localization of autoantibodies with the hmAchR M3 receptor-specific autoantibodies was observed in 10 out of 12 PBC-patients but none of the 5 healthy controls. Antibodies of the IgM type were not found to be affected.
For the first time, our data demonstrate the presence of autoantibodies to the hmAchR M3 in PBC patients. These findings might contribute to the understanding of the pathogenesis of this disease. Further studies have to focus on the functionality of hmAchR M3 autoantibodies in PBC patients.
Primary biliary cirrhosis (PBC) is an autoimmune liver disease characterized by chronic progressive destruction of the small intrahepatic bile ducts [1-4]. Its etiopathogenesis still remains unclear, although (i) genetic disposition, (ii) microorganisms, (iii) apoptotic processes, as well as (iv) environmental factors have been suggested to be of relevance for both development and maintenance of PBC [2,5-10].
Diagnostically, antimitochondrial antibodies (AMA) which mainly target the different subunits of the pyruvate dehydrogenase complex (PDC) play an important role and have been shown to occur in about 90% of all PBC patients [1-3,11]. However, these antibodies do not meet the classical criteria for an autoantibody-mediated autoimmune disease [12-15], i.e., induction of the disease in animal models by passive transfer of the disease-specific antibodies or via the application of the target antigen and the recovery from the disease due to a reduction of the titers of the disease-specific antibodies [3,16-19]. Therefore, the PDC-specific antibodies seem to be of no etiopathogenic relevance. Furthermore, since PDC is an antigen expressed in almost all cell types they do not explain the organ-specificity of PBC.
Deduced from recent studies on other autoimmune disorders, a novel etiopathogenic concept has been developed which is based on the involvement of functionally active autoantibodies against neurotransmitter receptors . As an example, patients with Pemphigus vulgaris exhibit autoantibodies to the alpha-9-acetylcholine-receptor which are responsible for the typical acantholysis . In addition, experimental and clinical studies verify the pathogenic role of antibodies to the beta1-adrenergic receptor in dilatative cardiomyopathy . Furthermore, in patients suffering from myasthenia gravis, autoantibodies to the alpha-1 subunit of the nicotinic acetylcholine receptor in muscles were shown to disturb neuromuscular signal transduction and mark the cells for complement mediated lysis . Interestingly, also in patients with M. Sjögren, an autoimmune disease quite often being associated with PBC [24,25], autoantibodies to human muscarinic acetylcholine receptors (hmAchR) of the M3 type were suggested to be one factor responsible for disease induction [26,27]. Moreover, since this specific receptor subtype was also detected on biliary cells but not on hepatocytes [28,29] we hypothesized that hmAchR M3-specific autoantibodies could play an important role in the etiopathogenesis of PBC. Thus, we now have undertaken a comprehensive study analyzing whether autoantibodies to the hmAchR of the M3 type could also be found in patients with PBC.
Our well-characterized PBC cohort at University Hospital Tübingen encompasses 50 patients (42 female, 8 male); furthermore, also 16 healthy controls gave their informed consent for this study, which was approved by the local ethics committee.
PBC patients: mean age was 57.7 ± 10.8 years (range 27 - 74 years); all patients exhibited typical PBC-associated laboratory parameters (such as elevated levels of alkaline phosphatase (AP), γ-glutamyltransferase (gGT), and/or IgM values). Liver biopsies had been performed in 23 patients and demonstrated PBC-specific lesions in all instances. 48 patients showed a positive reaction in the immunofluorescence test (IFT) to mitochondrial antigens on cryostat sections (AMA-positivity); in the remaining 2 AMA-negative patients PBC was evidenced either by liver biopsy or the presence of anti-PDC-antibodies by Western blotting analysis. 20 patients showed ANA (anti-nuclear antigen) reactivity in the IFT. 13 patients exhibited SMA (smooth muscle antigen) reactivity in the IFT. Elevation of IgM globulins were observed in 37 patients (> 230 mg/dl) and elevation of IgG levels in 14 patients (> 1.600 mg/dl). 44 patients were under therapy with ursodeoxycholic acid.
Controls: sera from 16 healthy blood donors from the University Hospital Tübingen were included in our study (female-to-male ratio was 10:6; mean age: 32 ± 8 years; range 20 - 48 years). All sera were checked for autoantibody reactivity by the IFT and were found to be serologically negative for AMA. 3 patients showed autoantibodies to ANA and another 3 patients to SMA.
Co-localization of PBC-specific antibodies with autoantibodies to the hmAchR M3 was studied using a Leica TCS SP2-x1 confocal laser scanning microscope and 'Leica confocal' software (Leica Biosystems GmbH, Nussloch, Germany). For this purpose, HT-29 human colon carcinoma cells were cultured in RPMI-1640 medium (BioWhittaker, Verviers, Belgium) supplemented with 10% heat-inactivated fetal calf serum (PAA Laboratories, Cölbe, Germany), 100 units of penicillin/ml, 0.1 mg streptomycin/ml and 10 mM HEPES (all from Gibco, Karlsruhe, Germany). Cells were grown at 37 °C in a 5% CO2 atmosphere and maintained in the log phase. Using a polyclonal anti-hmAchR M3 antibody, HT-29 cells were tested by Western blot analyses for expression of hmAchR of the M3 type (data not shown). They were seeded at 5 × 105/ml in 24 wells plates containing a sterile cover slip. Cells were allowed to adhere overnight and then washed twice with PBS (Gibco). Cells were fixed with 500 μl of 3.7% paraformaldehyde (Sigma, Deisenhofen, Germany) for 20 min at room temperature (RT) followed by three washing steps with 1 ml PBS/0.5% BSA (P-BSA), and blocking for 10 min in PBC/10% FCS at RT. After washing once with P-BSA, cells were permeabilized with 0.1% Triton X-100 (Roth, Karlsruhe, Germany) for 10 min at RT, washed three times with P-BSA. Labelling with primary antibodies (50 μl; 60 min at RT) employed (i) a rabbit anti-hmAchR M3 polyclonal antibody (poAb; Acris, Hiddenhausen, Germany), (ii) a mouse anti-Na+/K+-ATPase mAb (Biomol, Hamburg, Germany) and serum IgG fractions from (iii) PBC patients or (iv) healthy controls. Serum IgG from the respective individuals was purified as described  and diluted in PBS/1% BSA to a final concentration (f.c.) of 2.5 μg/ml.
After washing with P-BSA for three times, 50 μl of the secondary antibodies (goat anti-rabbit IgG, Alexa Fluor 488 conjugated (Invitrogen, Karlsruhe, Germany); goat anti-mouse IgG, Cy3 conjugated (Amersham Pharmacia, Freiburg, Germany); goat anti-human IgG, Alexa 633 conjugated (Invitrogen)) were added at a f.c. of 2 μg/ml in P-BSA for 30 min at RT in the dark. After three washing steps, cells were mounted on a slide (Langenbrinck, Emmendingen, Germany) using 7 μl mounting medium (Confocal-Matrix, Micro Tech Lab, Graz, Austria).
Sera were tested employing a 25-mer peptide ([31-33]; synthesized by Seqlab, Göttingen, Germany; amino acids 213 - 237, KRTVPPGECFIQFLSEPTITFGTAI; concentration of 10 μg/ml) of the hmAchR M3 protein by ELISA according to the method described [34,35]. Sera were diluted 1:100 [36,37]. The secondary anti-human IgG or IgM antibodies (Dianova, Hamburg, Germany) were used at a concentration of 0.5 μg/ml. The cut-off values were defined as the mean of the values from the 16 controls in addition to 2 standard deviations.
Sera were analyzed for the presence of autoantibodies to the hmAchR of the M3 type using membrane fractions of hmAchR M3 expressing Sf9 cells (Sigma, Deisenhofen, Germany) by Western blotting analysis following the method described [30,38]. Sera were diluted 1:200 in 5% milk powder (low fat; Roth, Karlsruhe, Germany) in TBST (10 mM Tris-HCl pH 7.4, 100 mM NaCl, 0.01% Triton). As secondary antibody horse radish peroxidase-conjugated anti-human IgG (1:4.000; DAKO, Hamburg, Germany) was used. Proteins were detected by the enhanced chemoluminescence (ECL) method (Amersham-Buchler, Germany).
Differences between the sera of the patient or control cohorts concerning reactivity to (i) the hmAchR of the M3 type or (ii) the 25-mer peptide were statistically evaluated using the Wilcoxon test (WinSTAT software); p ≤ 0.05 was defined as significant.
In order to investigate the presence of human muscarinic acetylcholine receptor M3 (hmAchR M3)-specific autoantibodies in PBC patients, we first addressed the question whether PBC-specific antibodies do co-localize with antibodies to the hmAchR M3. Therefore, HT-29 human colon carcinoma cells expressing the hmAchR M3 receptor (proven by Western blotting; data not shown) were fixed on cover slides and stained with sera from PBC patients (representative example given in Figure Figure1,1, lane A), or control sera IgG fractions from healthy donors (Figure (Figure1,1, lane B) as well as a commercially available polyclonal antibody to the hmAchR M3 (Figure (Figure1,1, lanes A+B, column 2); as a control for cell surface receptor staining, a Na+/K+-ATPase-specific antibody was used (Figure (Figure1,1, lane C, column 3).
As a result, overlaying of the hmAchR M3-specific antibody staining with staining by sera from PBC patients (Figure (Figure1,1, lane A, column 4) was found to exhibit a profound co-localization of detected antigens. In clear contrast, no co-localizing signals were found for the serum IgG fractions of healthy donors (Figure (Figure1,1, lane B, column 4). In total, co-localization of PBC-specific antibodies with the hmAchR M3-specific antibody was found to be present in 10 out of 12 tested PBC sera, but none of the tested control sera (Tab. (Tab.11).
In contrast to the staining with the Na+/K+-ATPase-specific mAb (Figure (Figure1,1, lane C, column 3), staining by the polyclonal hmAchR M3 antibody was not restricted to the cell membrane; an additional diffuse intracellular staining was detectable (Figure (Figure1,1, lanes A+B, column 2).
To assess whether PBC patients produce autoantibodies to the hmAchR of the M3 type, we next performed a Western blotting analysis using the membrane fraction of Sf9 cells over-expressing the recombinant hmAchR receptor protein (rhM3R) of the M3 type (Figure (Figure2).2). While all sera from four initially analyzed PBC patients clearly detected the typical bands of the PDC complex (Figure (Figure2,2, left lanes), hmAchR M3 receptor protein was recognized at 65 kDa by only 2 of the 4 PBC sera (Figure (Figure2,2, right lanes). Employment of a control serum from a healthy donor did not show any prominent band (Figure (Figure2,2, right panel).
Testing a larger cohort of PBC patients, we found a significantly elevated frequency of IgG type-autoantibodies to the recombinant hmAchR M3 receptor protein in sera from PDC-E2+ PBC patients 33%) versus the control group comprising healthy donors (7.7%) (Tab. (Tab.2).2). As an exception, only one healthy control displayed a hmAchR M3-specific band, while, as expected, none of the different subunits of the PDC was recognized by the same serum (data not shown).
The frequency of autoantibodies to hmAchR M3 receptor was also assessed by an ELISA using a 25-mer peptide of the 2nd extracellular loop of hmAchR M3, which has been suggested as the most important epitope of this receptor protein [31-33] (Figure (Figure3).3). As a result, we observed a significant difference in IgG reactivity between the PBC patient cohort and healthy controls (Figure (Figure3;3; bar 1 vs. bar 3).
With respect to the elevated frequency of anti-hmAchR M3 IgM-type reactivity in PBC patients (Figure (Figure3;3; bar 2) we also investigated the control cohort for IgM-type hmAchR M3-specific autoantibodies. However, there was no significant difference in the IgM antibody binding between the PBC patients and the healthy controls (Figure (Figure3;3; bar 2 vs. bar 4).
Differences between the PBC patients being ELISA positive or negative could not be found depending upon the demographic data. However the ELISA positive patients showed a heightened number of patients with elevated IgG (64%) and IgM (91%) levels as compared to the ELISA negative patients (enhanced IgG level: 18%, enhanced IgM level: 69%). With respect to the disease activity we observed that the histologies performed in 6 of the 11 ELISA positive patients, 3 patients showed a disease stage I-II and 3 patients a disease stage III-IV. In 17 out of the 39 patients being ELISA negative histologies were performed from which 12 patients showed a disease stage I-II and 3 patients a disease stage III-IV, while 2 patients were graded as stage II-III.
Autoantibodies to neurotransmitter receptors seem to be involved in the etiopathogenesis of a variety of autoimmune diseases [21-23,26,27]. There are several reports on in vitro and in vivo studies suggesting a role for autoantibodies to the hmAchR M3 subtype in the etiopathogenesis of the Sjögren's syndrome which often is associated with PBC [26,31,39,40]. This hypothesis is underlined by animal models employing non-obese diabetic (NOD) mice, which are well-known for hypofunction of their salivary glands. Passive transfer of monoclonal antibodies binding specifically to the rat mAchR M3 receptor protein into NOD-scid mice revealed a further diminished secretory function of these glands . In contrast, mice of the Igμ-null-NOD strain (completely lacking functionally active B lymphocytes) do not exhibit any such glandular dysfunction while passive transfer of IgG fraction from patients with M. Sjögren lead to a loss of secretory function  and application of F(ab')2 fragments from parental NOD mice diminished it. Concluding from this, autoantibodies to the hmAchR M3 receptor protein are suggested to be responsible for diminished secretion of the salivary gland cells due to an autoantibody-mediated desensitization of the receptor via internalization or degradation [43-45].
In our study, we now describe a hitherto unknown co-localization of IgG-type autoantibodies specific to the hmAchR M3 found in the sera of patients with PBC, but not in sera of healthy controls (Figure (Figure1).1). Of note, not only cell surface membranes were found to be stained by our polyclonal hmAchR M3 antibody; additionally, a diffuse intracellular staining was detectable (Figure (Figure1,1, lanes A+B, column 2). This effect was not found to be unspecific: employment of three different hmAchR M3-specific antibodies recognizing either (i) the intracellular C-terminus (as used for Figure Figure1),1), (ii) the extracellular N-terminal sequence or (iii) the 3rd intracellular domain of the receptor did not change this pattern (data not shown). Therefore, our finding may be in accordance with reports demonstrating internalization of the hmAchR M3 receptor protein [44,45].
Our further results now report a frequency of hmAchR M3-specific autoantibodies in PBC patients in the range of 22-33% (depending upon the detection technique and materials used). Interestingly, these data are comparable with data obtained from the literature for patients with Sjögren's syndrome, in whom autoantibodies were detected by ELISA in a frequency range of 9-40% [32,33,37]. In our study we tested the presence of these antibodies not routinely but only in patients with clinical features of M. Sjögren. Thus, identifying only one patient with typical symptoms of M. Sjögren, this patient was found to express anti SS-A/SS-B antibodies as detected by ELISA (data not shown). Interestingly, this patient also showed hmAchR M3-specific autoantibodies. Further studies have to show if there is a correlation between anti SS-A/SS-B reactivity and the occurrence of hmAchR M3-specific autoantibodies in PBC patients.
Our observation that autoantibodies to the hmAchR M3 receptor protein could be detected more frequently in Western blotting analysis than in the ELISA system (33% vs. 22%) may be due to the fact that in case of Western blotting the whole receptor molecule was used providing a variety of potential epitopes as compared to the peptide used for detection in the ELISA-based assay. Thus, the amino acid sequence of the 2nd extracellular loop as presented in our 25-mer peptide seems to represent not the only epitope, although in the Western blotting analysis a cross-reactivity of autoantibodies to similar muscarinic receptors cannot be excluded completely.
The comparison of the demographic, clinical and biochemical parameters of the patients being anti-M3R positive or negative using the ELISA system, suggests that the anti-M3R antibodies might occur more frequently in patients with an advanced disease. Since, however, in quite a lot of them no biopsies were performed, this observation has to be evaluated in more detail in further studies.
Importantly, hmAchR M3-specific autoantibodies have not been investigated in PBC before. There are, however, two reports on the autoantibody response to nicotinic acetylcholine receptors [46,47] demonstrating the recognition of these proteins by the respective autoantibodies in the majority of the PBC patients as well as patients with myasthenia gravis.
Taken together, our studies show again the presence of new specific autoantibodies in PBC patients different to AMA. Since AMA failed to be clearly related to the etiopathogenesis of PBC it is encouraging that several new antibodies have been characterized, which might be associated with disease stage  or with new concepts for the etiopathogenesis of PBC .
With respect to the literature and our own data, our concept of the expression of autoantibodies to the muscarinic AchR of the M3 type in patients with PBC could be of importance for the etiopathogenesis of PBC: (i) for the first time, our findings may explain the organ-specificity of the PBC disease since the hmAchR M3 is not expressed on hepatocytes but on cholangiocytes ; in addition, also the parasympathetic innervation of the biliary system may point to a role for these autoantibodies. (ii) The hmAchR M3 is also expressed on different glands; in this context it is well-known that PBC patients quite often display an affection of their salivary glands . (iii) Our concept may help to better understand the pathogenesis of PBC if the autoantibodies exert a functional activity in the PBC patients as it was shown for the autoantibodies of the patients with M. Sjögren [26,31,39,40]. Therefore, further studies will have to focus on the characterization of the hmAchR M3-specific autoantibodies with respect to an inhibitory or stimulatory effect on the hmAchR.
AMA: antimitochondrial antibodies; hmAchR M3: human muscarinic acetylcholine receptor of the M3 type; mAb: monoclonal antibody; OADC: 2-oxoacid dehydrogenase complex; PBC: primary biliary cirrhosis; PDC: pyruvate dehydrogenase complex
The authors declare that they have no competing interests.
CPB, KB, GMS, and KL performed the experiments. GMS and SW contributed equally to this paper and share senior authorship. GMS, CPB, PAB and SW designed research, analyzed data and wrote the manuscript. MG helped discussing the data. They all read and approved the final manuscript.
The pre-publication history for this paper can be accessed here:
This work was kindly supported by grants from the Deutsche Forschungsgemeinschaft (WE-1801/2-4, GRK1302, SFB 685; SW), the German Bundesministerium für Bildung und Forschung (Hep-Net; GMS and SW), the Interdisciplinary Center of Clinical Research Tübingen (IZKF; Fö. 01KS9602; KL, SW), the Wilhelm-Sander-Stiftung (2004.099.1; SW), the Landesforschungsschwerpunktprogramm of the Ministry of Science, Research and Arts of the Land Baden-Wuerttemberg (1423-98101; SW) and from the Fortuene Program of the Medical Faculty of the University of Tübingen (No. F1281399; CPB and GMS and No. 1250-0-0; KL).