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Case Report/Case Series |

Persistence of Autoreactive IgA-Secreting B Cells Despite Multiple Immunosuppressive Medications Including Rituximab FREE

Yong He, MD1; Michiko Shimoda, PhD1; Yoko Ono, MD1; Itzel Bustos Villalobos, MD, PhD1; Anupam Mitra, MD1; Thomas Konia, MD2; Sergei A. Grando, MD3; John J. Zone, MD4; Emanual Maverakis, MD1
[+] Author Affiliations
1Department of Dermatology, University of California, Davis, School of Medicine, Sacramento
2Department of Pathology, University of California, Davis, School of Medicine, Sacramento
3Department of Dermatology, University of California, Irvine, School of Medicine
4Department of Dermatology, University of Utah School of Medicine, Salt Lake City
JAMA Dermatol. 2015;151(6):646-650. doi:10.1001/jamadermatol.2015.59.
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Published online

ABSTRACT

Importance  Immunobullous diseases mediated by IgA are often difficult to manage, but to date no mechanism has been proposed. Rituximab is an anti-CD20 monoclonal antibody that has demonstrated good efficacy in the treatment of refractory mucous membrane pemphigoid. However, not all cases of mucous membrane pemphigoid respond to rituximab. Herein we present a case of treatment-refractory mucous membrane pemphigoid and propose a mechanism to explain the lack of response to therapy.

Observations  Before treatment, direct immunofluorescent examination of a biopsy sample from the patient’s perilesional skin demonstrated linear deposition of IgG and IgA along the dermoepidermal junction. After a multidrug immunosuppressive regimen that included rituximab, results of a second biopsy demonstrated only IgA along the dermoepidermal junction. This finding correlated well with flow cytometry data from the same patient that demonstrated a persistent population of IgA-secreting plasmablasts/plasma cells, despite depletion of CD20+ cells. In addition, results of immunohistochemical analysis of the perilesional skin remained positive for CD19 and CD138 immune cells (plasmablast/plasma cell markers).

Conclusions and Relevance  These findings suggest that current available immunosuppressive medications, including rituximab, cannot eliminate IgA-secreting plasmablasts/plasma cells, which are likely central to the pathophysiology of IgA-mediated immunobullous diseases. Future studies are needed to develop alternative therapeutic strategies that target autoreactive IgA-secreting plasmablasts/plasma cells.

Figures in this Article

INTRODUCTION

Mucous membrane pemphigoid (MMP), also known as cicatricial pemphigoid, constitutes a heterogeneous group of autoimmune blistering diseases that result from autoantibodies directed against epidermal basement membrane proteins.14 Although presentations vary, patients can have involvement of their conjunctiva, sometimes experiencing a progressive disease course resulting in vision loss.

Rituximab is a chimeric murine-human anti-CD20 monoclonal antibody that has demonstrated good efficacy in the treatment of severe refractory immunobullous diseases, including difficult-to-treat cases of MMP that involve the conjunctiva, trachea, and oropharynx.59 The mechanism of action of rituximab is not entirely clear, but the drug depletes CD20-expressing cells, which constitute the majority of B cells. In most cases, this depletion results in a decrease in the circulating levels of autoreactive antibodies and a resolution of the autoimmune disease state. However, not all patients respond to rituximab. Herein we present a case of refractory MMP and propose that the preferential depletion of autoreactive IgG- but not IgA-secreting plasmablasts/plasma cells was responsible for the patient’s treatment-resistant disease course.

REPORT OF A CASE

An older man presented to the Department of Dermatology, University of California, Davis, with generalized cutaneous bullae and oral erosions. A skin biopsy specimen underwent direct immunofluorescence and revealed a strong continuous linear basement membrane zone deposition of IgG, IgA, and C3 (Mayo Clinic, Rochester, Minnesota). In addition, BP180- and BP230-specific IgG were detected by enzyme-linked immunosorbent assay (titer, 1:11 for both; ARUP Laboratories, Salt Lake City, Utah). The patient subsequently developed bilateral conjunctival bullae and was treated with prednisone (80 mg/d), dapsone (100 mg twice daily), mycophenolate mofetil hydrochloride (1000 mg twice daily), and niacinamide (500 mg 3 times daily), resulting in minimal improvement. Rituximab (375 mg/m2 of body surface area once weekly for 4 weeks), intravenous immunoglobulin (400 mg/kg daily for 5 days), and intravenous pulsed cyclophosphamide (15 mg/kg once monthly for 5 months) were sequentially added to his treatment regimen, again resulting in minimal improvement (Figure 1A). Results of peripheral blood CD19+ counts persisted at less than 1%, confirming rituximab activity. Disease progression continued and eventually resulted in worsening oral ulcerations, odynophagia, and significant ocular scarring (Figure 1B). The patient developed macular edema, and prednisone eye drops were added to his treatment regimen. His therapy was also switched from mycophenolate mofetil to azathioprine sodium, and he received several additional cycles of intravenous immunoglobulin, again with minimal improvement. After the patient did not respond to rituximab, intravenous immunoglobulin, and cyclophosphamide, a second biopsy specimen was obtained for direct immunofluorescence. The results demonstrated deposition of linear IgA, sparse granular C3, but no IgG along the dermoepidermal junction (Figure 1C). Results of a second enzyme-linked immunosorbent assay confirmed resolution of autoreactive BP180- and BP230-specific IgG (ARUP Laboratories).

Place holder to copy figure label and caption
Figure 1.
Persistent Autoreactive IgA Despite Aggressive Immunosuppressive Therapy

A, Timeline of treatment course and CD19+ cell depletion after rituximab treatment. After rituximab administration (represented by downward-facing antibody symbols), CD19 cells (diamonds) were rapidly depleted and remained persistently depleted without additional courses of rituximab. Each upward-facing antibody symbol represents 5 days of intravenous immunoglobulin (IVIG) administration (400 mg/kg per day). Cyclophosphamide (solid black circles with attached lines) was administered as an intravenous pulse of 15 mg/kg. Diamond markers represent points when CD19 markers were checked, corresponding to the effectiveness of rituximab B cell depletion. B, Clinical photograph of the left eye demonstrating the ocular sequelae of persistent mucous membrane pemphigoid, including conjunctival hyperemia, corneal erosions, and lower lid symblepharon. C, Direct immunofluorescence demonstrating linear deposition of IgA along the dermoepidermal junction; IgG was undetectable (arrowhead). Direct immunofluorescence was performed by the Dermatopathology Service of University of California, Davis, School of Medicine. D, Immunohistochemical analysis demonstrates presence of CD19+ (original magnification ×20 [left] and ×40 [right]) and CD138+ (original magnification ×20 [left] and ×40 [right]) plasmablasts and plasma cells in the dermis.

Graphic Jump Location

Given that the results of direct immunofluorescence studies demonstrated persistent deposition of autoreactive IgA, despite aggressive immunosuppressive therapy, peripheral blood was drawn for a detailed characterization of the treatment-resistant B cells. The medical ethics committee of the University of California, Davis, School of Medicine approved all aspects of this study according to the Declaration of Helsinki principles. Peripheral blood mononuclear cells were analyzed for expression of CD19, CD20, and CD27. In contrast to blood samples from healthy individuals, circulating CD20CD19+CD27+ cells representative of the plamablasts/plasma cell population (red outline) occupied a large proportion of the B-cell pool in the treated patient (17.7% vs 0.7%) (Figure 2A). Further analysis revealed that IgA-expressing cells were greatly expanded within the CD20CD19+CD27+ plasmablast/plasma cell population after treatment, conservatively measured at 33.7% (Figure 2B). An increased population of CD20+CD19+CD27+ IgA-expressing memory B cells (blue outline) was also detected (25.9%) after treatment (Figure 2C). Thus, in our patient, IgA-expressing plasmablasts/plasma cells were strongly resistant to aggressive immunosuppressive therapy that included B-cell depletion with rituximab.

Place holder to copy figure label and caption
Figure 2.
Persistence of IgA-Secreting Plasmablasts/Plasma Cells After Aggressive Immunosuppressive Therapy

A, Left, Levels of CD3CD14CD19+ cells are depleted after rituximab treatment (0.1% vs 7.3% in healthy control sample; P = .002). Middle, CD20CD27+ plasmablasts/plasma cells (red outline) represent a large proportion of the residual CD19+ cells after treatment (17.7% vs 0.7% in healthy control; P = .008). Right, Bar graphs illustrate changes in cell levels. PBMC indicates peripheral blood mononuclear cell. B, Levels of IgA-secreting cells (arrowhead) are increased in the CD20CD19+CD27+ population (originating from the red outline in part A) after treatment. C, Levels of IgA-secreting cells are increased within the CD20+CD19+CD27+ population (originating from the blue outline in part A) after treatment.

Graphic Jump Location

To gain further insight into the origin of the autoreactive IgA antibodies, the posttreatment perilesional skin biopsy specimen was reevaluated using immunohistochemical analysis for CD19 and CD138, which demonstrated the presence of CD19+ and CD138+ plasmablasts/plasma cells (Figure 1D). These immune cells are presumed to contribute to the pathogenic autoreactive IgA antibodies that were detected by direct immunofluorescence (Figure 1C). Furthermore, indirect immunofluorescence performed on a normal skin specimen with posttreatment serum using the salt split technique demonstrated IgA reactivity to the epidermal side of the split at a titer of 1:160 (ARUP Laboratories). No IgG was detectable via indirect immunofluorescence.

DISCUSSION

Mei et al10 recently reported that rituximab fails to deplete self-replenishing IgA B cells of mucosal origin, although their study lacked patients with IgA-mediated autoimmunity. We speculate that the treatment-resistant peripherally circulating IgA-expressing plasmablasts/plasma cells in our patient are also derived from a self-sufficient population of tissue-resident B cells that are thought to be inherently resistant to anti-CD20 therapy.10,11 Our patient’s MMP did not respond to several additional immunosuppressive medications in addition to rituximab. We therefore hypothesize that his autoreactive IgA-secreting cells are very slowly regenerating or are a long-lived population. Otherwise, they should have been susceptible to the nitrogen mustard–alkylating agent, cyclophosphamide, which is especially toxic to proliferating cells.

Also noteworthy was the depletion of B cells longer than 1000 days after rituximab administration in our patient. This duration has been reported rarely in published studies.12 The patient is now being treated with combination therapy consisting of prednisone, 20mg/d, leflunomide, 20 mg/d, and dapsone, 100 mg twice daily.

CONCLUSIONS

To our knowledge, this report is the first to show that autoreactive IgA-secreting B cells are resistant to multiple immunosuppressive medications, including rituximab. Our study, although limited to a single case, may explain why MMP resulting from autoreactive IgA and IgG manifests more severe disease when compared with MMP mediated by IgG alone.2 Future studies are needed to develop therapeutic strategies to target autoreactive rituximab-resistant IgA-expressing plasmablasts/plasma cells.

ARTICLE INFORMATION

Accepted for Publication: January 10, 2015.

Corresponding Author: Emanual Maverakis, MD, Department of Dermatology, University of California, Davis, School of Medicine, 3301 C St, Ste 1400, Sacramento, CA 95816 (emaverakis@ucdavis.edu).

Published Online: April 22, 2015. doi:10.1001/jamadermatol.2015.59.

Author Contributions: Drs He and Maverakis had full access to all the data in the study and take responsibility for the integrity of the data and the accuracy of the data analysis.

Study concept and design: He, Ono, Grando, Zone, Maverakis.

Acquisition, analysis, or interpretation of data: He, Shimoda, Ono, Villalobos, Mitra, Konia, Grando, Maverakis.

Drafting of the manuscript: He, Shimoda, Ono, Mitra, Grando, Maverakis.

Critical revision of the manuscript for important intellectual content: He, Shimoda, Villalobos, Konia, Grando, Zone, Maverakis.

Statistical analysis: Ono, Grando, Maverakis.

Obtained funding: Grando, Maverakis.

Administrative, technical, or material support: Shimoda, Villalobos, Mitra, Maverakis.

Study supervision: Grando, Zone.

Conflict of Interest Disclosures: None reported.

Funding/Support: This study was supported by career awards from the Howard Hughes Medical Institute and the Burroughs Wellcome Fund (Dr Maverakis) and by New Innovator Award 1DP2 OD008752 from the National Institutes of Health.

Role of the Funder/Sponsor: The funding sources had no role in the design and conduct of the study; collection, management, analysis, and interpretation of the data; preparation, review, or approval of the manuscript; and decision to submit the manuscript for publication.

REFERENCES

Schmidt  E, Skrobek  C, Kromminga  A,  et al.  Cicatricial pemphigoid: IgA and IgG autoantibodies target epitopes on both intra- and extracellular domains of bullous pemphigoid antigen 180. Br J Dermatol. 2001;145(5):778-783.
PubMed   |  Link to Article
Schmidt  E, Zillikens  D.  Pemphigoid diseases. Lancet. 2013;381(9863):320-332.
PubMed   |  Link to Article
Kourosh  AS, Yancey  KB.  Pathogenesis of mucous membrane pemphigoid. Dermatol Clin. 2011;29(3):479-484, x.
PubMed   |  Link to Article
Chan  LS, Ahmed  AR, Anhalt  GJ,  et al.  The first international consensus on mucous membrane pemphigoid: definition, diagnostic criteria, pathogenic factors, medical treatment, and prognostic indicators. Arch Dermatol. 2002;138(3):370-379.
PubMed   |  Link to Article
Foster  CS, Chang  PY, Ahmed  AR.  Combination of rituximab and intravenous immunoglobulin for recalcitrant ocular cicatricial pemphigoid: a preliminary report. Ophthalmology. 2010;117(5):861-869.
PubMed   |  Link to Article
Le Roux-Villet  C, Prost-Squarcioni  C, Alexandre  M,  et al.  Rituximab for patients with refractory mucous membrane pemphigoid. Arch Dermatol. 2011;147(7):843-849.
PubMed   |  Link to Article
Li  Y, Foshee  JB, Sontheimer  RD.  Sustained clinical response to rituximab in a case of life-threatening overlap subepidermal autoimmune blistering disease. J Am Acad Dermatol. 2011;64(4):773-778.
PubMed   |  Link to Article
Ross  AH, Jaycock  P, Cook  SD, Dick  AD, Tole  DM.  The use of rituximab in refractory mucous membrane pemphigoid with severe ocular involvement. Br J Ophthalmol. 2009;93(4):421-422, 548.
PubMed   |  Link to Article
Schumann  T, Schmidt  E, Booken  N, Goerdt  S, Goebeler  M.  Successful treatment of mucous membrane pemphigoid with the anti–CD-20 antibody rituximab. Acta Derm Venereol. 2009;89(1):101-102.
PubMed   |  Link to Article
Mei  HE, Frölich  D, Giesecke  C,  et al.  Steady-state generation of mucosal IgA+ plasmablasts is not abrogated by B-cell depletion therapy with rituximab. Blood. 2010;116(24):5181-5190.
PubMed   |  Link to Article
Raderer  M, Jäger  G, Brugger  S,  et al.  Rituximab for treatment of advanced extranodal marginal zone B cell lymphoma of the mucosa-associated lymphoid tissue lymphoma. Oncology. 2003;65(4):306-310.
PubMed   |  Link to Article
Lu  TY-T, Jónsdóttir  T, van Vollenhoven  RF, Isenberg  DA.  Prolonged B-cell depletion following rituximab therapy in systemic lupus erythematosus: a report of two cases [published correction appears in Ann Rheum Dis. 2009;68(5):764]. Ann Rheum Dis. 2008;67(10):1493-1494.
PubMed   |  Link to Article

Figures

Place holder to copy figure label and caption
Figure 1.
Persistent Autoreactive IgA Despite Aggressive Immunosuppressive Therapy

A, Timeline of treatment course and CD19+ cell depletion after rituximab treatment. After rituximab administration (represented by downward-facing antibody symbols), CD19 cells (diamonds) were rapidly depleted and remained persistently depleted without additional courses of rituximab. Each upward-facing antibody symbol represents 5 days of intravenous immunoglobulin (IVIG) administration (400 mg/kg per day). Cyclophosphamide (solid black circles with attached lines) was administered as an intravenous pulse of 15 mg/kg. Diamond markers represent points when CD19 markers were checked, corresponding to the effectiveness of rituximab B cell depletion. B, Clinical photograph of the left eye demonstrating the ocular sequelae of persistent mucous membrane pemphigoid, including conjunctival hyperemia, corneal erosions, and lower lid symblepharon. C, Direct immunofluorescence demonstrating linear deposition of IgA along the dermoepidermal junction; IgG was undetectable (arrowhead). Direct immunofluorescence was performed by the Dermatopathology Service of University of California, Davis, School of Medicine. D, Immunohistochemical analysis demonstrates presence of CD19+ (original magnification ×20 [left] and ×40 [right]) and CD138+ (original magnification ×20 [left] and ×40 [right]) plasmablasts and plasma cells in the dermis.

Graphic Jump Location
Place holder to copy figure label and caption
Figure 2.
Persistence of IgA-Secreting Plasmablasts/Plasma Cells After Aggressive Immunosuppressive Therapy

A, Left, Levels of CD3CD14CD19+ cells are depleted after rituximab treatment (0.1% vs 7.3% in healthy control sample; P = .002). Middle, CD20CD27+ plasmablasts/plasma cells (red outline) represent a large proportion of the residual CD19+ cells after treatment (17.7% vs 0.7% in healthy control; P = .008). Right, Bar graphs illustrate changes in cell levels. PBMC indicates peripheral blood mononuclear cell. B, Levels of IgA-secreting cells (arrowhead) are increased in the CD20CD19+CD27+ population (originating from the red outline in part A) after treatment. C, Levels of IgA-secreting cells are increased within the CD20+CD19+CD27+ population (originating from the blue outline in part A) after treatment.

Graphic Jump Location

Tables

References

Schmidt  E, Skrobek  C, Kromminga  A,  et al.  Cicatricial pemphigoid: IgA and IgG autoantibodies target epitopes on both intra- and extracellular domains of bullous pemphigoid antigen 180. Br J Dermatol. 2001;145(5):778-783.
PubMed   |  Link to Article
Schmidt  E, Zillikens  D.  Pemphigoid diseases. Lancet. 2013;381(9863):320-332.
PubMed   |  Link to Article
Kourosh  AS, Yancey  KB.  Pathogenesis of mucous membrane pemphigoid. Dermatol Clin. 2011;29(3):479-484, x.
PubMed   |  Link to Article
Chan  LS, Ahmed  AR, Anhalt  GJ,  et al.  The first international consensus on mucous membrane pemphigoid: definition, diagnostic criteria, pathogenic factors, medical treatment, and prognostic indicators. Arch Dermatol. 2002;138(3):370-379.
PubMed   |  Link to Article
Foster  CS, Chang  PY, Ahmed  AR.  Combination of rituximab and intravenous immunoglobulin for recalcitrant ocular cicatricial pemphigoid: a preliminary report. Ophthalmology. 2010;117(5):861-869.
PubMed   |  Link to Article
Le Roux-Villet  C, Prost-Squarcioni  C, Alexandre  M,  et al.  Rituximab for patients with refractory mucous membrane pemphigoid. Arch Dermatol. 2011;147(7):843-849.
PubMed   |  Link to Article
Li  Y, Foshee  JB, Sontheimer  RD.  Sustained clinical response to rituximab in a case of life-threatening overlap subepidermal autoimmune blistering disease. J Am Acad Dermatol. 2011;64(4):773-778.
PubMed   |  Link to Article
Ross  AH, Jaycock  P, Cook  SD, Dick  AD, Tole  DM.  The use of rituximab in refractory mucous membrane pemphigoid with severe ocular involvement. Br J Ophthalmol. 2009;93(4):421-422, 548.
PubMed   |  Link to Article
Schumann  T, Schmidt  E, Booken  N, Goerdt  S, Goebeler  M.  Successful treatment of mucous membrane pemphigoid with the anti–CD-20 antibody rituximab. Acta Derm Venereol. 2009;89(1):101-102.
PubMed   |  Link to Article
Mei  HE, Frölich  D, Giesecke  C,  et al.  Steady-state generation of mucosal IgA+ plasmablasts is not abrogated by B-cell depletion therapy with rituximab. Blood. 2010;116(24):5181-5190.
PubMed   |  Link to Article
Raderer  M, Jäger  G, Brugger  S,  et al.  Rituximab for treatment of advanced extranodal marginal zone B cell lymphoma of the mucosa-associated lymphoid tissue lymphoma. Oncology. 2003;65(4):306-310.
PubMed   |  Link to Article
Lu  TY-T, Jónsdóttir  T, van Vollenhoven  RF, Isenberg  DA.  Prolonged B-cell depletion following rituximab therapy in systemic lupus erythematosus: a report of two cases [published correction appears in Ann Rheum Dis. 2009;68(5):764]. Ann Rheum Dis. 2008;67(10):1493-1494.
PubMed   |  Link to Article

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