Mucous membrane pemphigoid: clinical aspects, immunopathological features and therapy

ARTICLE

Auteur(s) : Daniela Bruch-Gerharz¹, Michael Hertl², Thomas Ruzicka³

¹Department of Dermatology, Heinrich-Heine-University, P.O. Box 101007, D-40001 Duesseldorf, Germany
²Department of Dermatology, Faculty of Medicine, Philipps-University of Marburg, Germany
³Department of Dermatology, Faculty of Medicine, Ludwig-Maximilians-University of Munich, Germany

accepté le 4 Janvier 2007

Clinical course and manifestations

Mucous membrane pemphigoid typically starts with recurring vesicles or bullae on either a mucous membrane (figure 1A-D) or a skin area (figure 1E, F) usually adjacent to one of the orifices, and exhibits a pronounced tendency to scarring. Many patients have primary oral involvement of gingiva, buccal mucosa, alveolar ridge, hard and soft palate (figure 1D), tongue and lower lip. The most common oral manifestation is desquamative gingivitis, characterized by gingival erythema and glaze [7]. Severe involvement is manifested by desquamation with blisters or ulcers [3]. Postinflammatory atrophy in the mouth may imitate the white tracery of lichen planus. Adhesions between the buccal mucosa and the alveolar process or around the uvula and tonsillar fossae suggest the diagnosis. Extension of the disease to the larynx or esophagus can give rise to strictures necessitating surgical intervention [8]. Deafness from involvement of the middle ear may develop [9].

The conjunctiva is the second most common site of involvement. Conjunctival lesions usually start in one eye but involve the other within a few years (figure 1A). The onset of symptoms may be a simple catarrhal conjunctivitis which lasts for years, with alternating periods of activity and remission. Typically, development of the conjunctival blisters leads to symblepharon (fusion of the bulbar and palpebral conjunctiva) (figure 1B). Patients who have ocular involvement often present with dry eyes that result from blocked tear gland openings, accompanied by conjunctival scarring and inverted lashes. These complications worsen gradually and tend to lead to corneal ulceration and consequently opacification (figure 1C) [10, 11].

Some patients have recurring genital lesions (adhesions between the prepuce and the glans penis, and in the female between the labia majora) that are highly suggestive of mucous membrane pemphigoid (figure 1E) [2, 11]. Eventually, urethral stenosis, narrowing of the vaginal orifice, and other manifestations of external genital dysfunction may become troublesome. Patients who have anal lesions often present with spasm and pain on defecation [1]. Anal vesicles and erosions can lead to scarring and in severe cases may cause anal stenosis.

Prominent skin lesions (recurring vesicles or bullae) and extramucosal signs only rarely dominate the clinical picture [12]. Two types of skin lesions may occur, the most common being a generalized bullous eruption on the head and upper aspect of the trunk similar to that of bullous pemphigoid, but of transient nature. The second is a localized erythematous plaque, which often manifests near affected mucosal surfaces and becomes the site of recurring bullae with significant scarring. On the scalp, cicatricial alopecia may develop [6]. Occasionally, patients with widespread skin lesions present with vegetating and vesiculo-pustular lesions (“vegetating cicatricial pemphigoid”) [13]. Milia formation may be associated with secondary scarring (figure 1G).

Phenotypic variants

A first group of patients shows pure ocular disease. These patients rarely show circulating immunoglobulin (Ig) G antibodies of IgG reactive against the classical bullous pemphigoid (BP) antigens. It is noteworthy, however, that patients with predominant ocular pemphigoid may produce IgG antibodies against the β4 integrin subunit [14] or IgA antibodies reacting with an as yet uncharacterized 45 kd antigen [15]. Another group is represented by the concomitant appearance of mucosal and skin lesions as well as circulating IgG and IgA autoantibodies. These patients demonstrate serologic reactivity against bullous pemphigoid (BP) antigens and the soluble extracellular domains of BP180 [16]. The oral pemphigoid variant BP180 includes patients with oral involvement but no skin or other mucosal involvement. Most of these patients show linear basal membrane zone deposits of IgG on direct immunofluorescence, and only recently circulating antibodies directed against an epitope within the integrin α6 subunit has been identified [17]. Oral pemphigoid may respond to topical therapy with glucocorticoids and tacrolimus or systemic treatment with dapsone. Another major group includes patients with blistering at multiple mucosal surfaces, without any cutaneous involvement.

A last subgroup is immunochemically distinct and includes patients with anti-laminin 5 antibodies [18]. These patients have circulating IgG autoantibodies which bind to the dermal side of saline-split human skin (see below) and recognize laminin 5 (epiligrin), a component of the laminina lucida of the dermoepidermal basement membrane zone. Laminin 5 is a ligand for BP180 and also interacts with collagen VII of the anchoring fibrils, thus connecting basal keratinocytes via the basement membrane zone with the dermis. Patients with anti-laminin 5 mucous membrane pemphigoid seem to have an increased risk of internal malignancy [18, 19].

Pathological features and pathogenesis

The pathological hallmark of mucous membrane pemphigoid is a subepithelial loss of adhesion, which can result in permanent scarring of the affected area, particularly the conjunctiva [2]. Lesions have a predilection for the mucous membranes and they are histologically indistinguishable from bullous pemphigoid. Inflammatory cells are typically perivascular in location, but they may diffusely infiltrate the stroma. The composition of the infiltrate varies depending on the stage of disease activity and the affected site. In general, it is composed of lymphocytes, histiocytes, scattered neutrophils and eosinophils (figure 2A) [21]; plasma cells predominate in oral, genital and anal lesions, whereas ocular lesions reportedly contain substantial numbers of mast cells. In ocular lesions, extensive fibrin deposition has been found that may sustain a continuous pathologic wound healing process; fibrosis is present in more developed lesions, in which the stroma is being degraded [21-24].

Ultrastructural analysis has demonstrated that blister formation occurs within the lamina lucida. In ocular lesions, the normal loosely-connected conjunctival epithelial cells become closely interconnected with increased numbers of desmosomes [25, 26].

Early symptoms of mucous membrane pemphigoid are widely believed to result from an antibody-mediated process of epithelial detachment, although the underlying molecular mechanisms are largely unknown [20]. Experimental in vivo and in vitro models of blister formation suggest that the autoantibodies target adhesion molecules within the basal membrane, interfering with their structural integrity and function [27, 28]. In some lesions, autoantibodies may impair keratinocyte adhesion through steric hindrance or by eliciting a complement-mediated inflammatory reaction at the basement membrane zone [29]. In others, additional amplification factors including inflammatory cytokines or activated CD4⁺ T cells may be necessary to induce the disruption of the basement membrane zone.

Collectively, the patterns of epithelial detachment are heterogeneous among patients, but homogenous within active lesions from the same patient. Consequently, mucous membrane pemphigoid may not be a distinct disease entity, but rather a series of syndromes with different causes and pathogenetic mechanisms (e.g. antibody- and complement-mediated injury, cellular-mediated immune injury, or primary keratinocyte abnormality). Translationed evidence suggests that IgG autoantibodies are the initiators of the immune pathogenesis since IgG titers against BP180 and laminin 5 were found to relate to the clinical activity of the pemphigoids, but also IgG antibodies against laminin 5 in mucous membrane pemphigoid, as recently suggested [30, 31].

Etiology

Immunological features

Direct immunofluorescence

Indirect immunofluorescence

The clinical subsets of mucous membrane pemphigoid have been shown to vary in their IIF sensitivity. Positive results were found in 81% of patients with mucocutaneous disease, 18% of patients with mucosal disease only, and 7% of patients with ocular disease only [4]. Korman and Watson developed a technique that utilizes concentrated serum as substrate in salt-split IIF studies to detect very low titer antibodies in patients with suspected but previously unproven autoimmune-mediated diseases of the mucous membranes [46]. An analysis using an indirect enzyme-linked immunosorbent assay with monoclonal antibodies identified IgG1 and IgG4 as the main IgG subclasses [47].

Immunoelectron microscopy

Target autoantigens

Laminin 5 (epiligrin), an adhesion molecule composed of α3, β3 and γ2 chains, is localized to anchoring filaments within the lamina lucida and acts as a ligand for α3β1 and α6β4 integrins as well as BP180 [51-53]. It also binds the NC domain of type VII collagen, thereby linking the hemidesmosomes of basal epidermal keratinocytes (via α6β4 integrin and BP180) and the anchoring fibrils of the dermis (via type VII collagen). Experimental evidence indicates that autoantibodies against laminin 5 interfere with the adhesive function of this molecule causing detachment of keratinocytes from the basal membrane zone. By the use of immunoprecipitation it has been demonstrated that mucous membrane pemphigoid patients with anti-laminin 5 autoantibodies may also have autoantibodies against laminin 6, which shares the same α3 subunit suggesting that both are co-targets for these autoantibodies [54, 55]. Although some studies suggest that patients with anti-laminin 5 antibodies may represent a minority of patients with mucous membrane pemphigoid, further work will be necessary to clarify this point. Interestingly, one case of mucous membrane pemphigoid has been reported with autoantibodies directed against both laminin 5 and BP180, which indicates a possible role for epitope spreading within these ligands in the dermoepidermal basement membrane zone [56].

Bullous pemphigoid antigen 2 (BP180 or type XVII collagen) forms a part of the anchoring filament complex together with laminin 5, and also appears to function as an adhesion molecule [57]. BP180 has been shown to span the lamina lucida and to interact with laminin 5 in the lamina densa. Immunoblotting studies have identified at least two epitopes on the extracellular domain of BP180 recognized by mucous membrane pemphigoid autoantibodies located in the NC16a domain and the COOH-terminus which are also targets recognized by autoantibodies in bullous pemphigoid [30, 31, 58]. Electron microscopy localized BP180 autoantibodies of mucous membrane pemphigoid at the lower lamina lucida and lamina densa, whereas BP180 autoantibodies of bullous pemphigoid were found at the upper lamina lucida immediately below the hemidesmosome [59]. The different localization of target epitopes may help to explain the fact that lesions in bullous pemphigoid are not scarring, whereas mucous membrane pemphigoid has a propensity for scarring and tissue destruction. Possibly, in mucous membrane pemphigoid the basement membrane zone is disrupted at a location deeper than in bullous pemphigoid, resulting in an inflammatory response in the area of the lamina densa. Further investigations will be needed to determine the precise mechanism by which scarring in mucous membrane pemphigoid occurs.

The β4 integrin subunit in association with the α6 subunit forms a transmembrane integrin that is an integral part of the epidermal hemidesmosome and is involved in signal transduction [17, 60]. Autoantibodies directed against the β4 integrin subunit are presumably pathogenic in a subgroup of patients with ocular mucous membrane pemphigoid [14, 61]. In addition, immunoblotting revealed 168 kd and 45 kd antigens in mucosal pemphigoid that have to be further characterized [15, 62].

In summary, there is evidence that the autoantibodies in mucous membrane pemphigoid interfere with the adhesive function of their target molecules causing detachment of keratinocytes from the basal membrane zone [20, 21]. Supporting evidence comes from the observation that mutations in the genes encoding for the polypeptide chains of these molecules cause the lethal (laminin 5) and also non-lethal variants (laminin 5, BP180,β4 integrin subunit) of junctional epidermolysis bullosa [63-65]. These severe, inherited subepidermal blistering diseases also affect the skin, oropharynx and other epithelial-lined tissues and are associated with secondary atrophy (scarring).

Diagnosis and prognosis

Probably through immunological effects, a number of drugs (topical glaucoma medications, clonidine, practolol) have been found to be capable of producing an eruption strikingly similar to mucous membrane pemphigoid, but limited only to the eyes [73, 74]. The MHC class II genes associated with this so-called pseudo-ocular pemphigoid are different from those with ocular mucous membrane pemphigoid and there are definitive serological differences [74].

Table 1 provides a representative list of findings in other autoimmune bullous skin disorders that are clues to specific diagnoses. When the initial evaluation does not suggest a definite diagnosis, repeated mucosal or skin biopsies and immunoserological analyses after several months are advised.

The evolvement of symptoms and the clinical course of mucous membrane pemphigoid in an individual patient is largely unpredictable. However, a combination of both initial clinical score and initial IIF data may provide valuable prognostic information [75]. Irreversible epithelial injury and scarring of the mucosal surfaces may result from repeated episodes of disease flares and the ability of corticosteroids to speed recovery from relapses often diminishes with time. Persistent signs of epithelial injury are fibrous adhesions of the upper aerodigestive tract or corneal opacities, and the majority of patients with eye involvement eventually develop amaurosis [76].

Studies on the natural history of the disease have provided important prognostic information that is useful in the assessment and management of mucous membrane pemphigoid. Frequent relapses in the first years, a progressive course from the onset, and early permanent ocular lesions are predictive of a more severe clinical course [4, 76]. Patients with serious secondary complications (recurrent infection and malnutrition) have a poor prognosis. Life expectancy may be shortened slightly; in rare cases, patients with fulminant disease die within months after the onset of disease.
Table 1 Differential diagnosis of mucous membrane pemphigoid (MMP)

Treatment

Principles of therapy

Relapsing mucous membrane pemphigoid and the management of symptoms

Ocular Lesions. The extent and progression of ocular disease as well as treatment options can be monitored according to the staging system of Foster [11]. A potentially useful topical therapy for ocular lesions is tacrolimus [87], although most patients with ocular pemphigoid require systemic therapy. Oral corticosteroids (for example a brief course of oral methylprednisolone) are often used to treat clinically significant relapses of ocular disease in an attempt to hasten recovery. The use of dapsone with or without corticosteroids has also been recommended as a first-line therapy for patients with moderate ocular disease [79, 88]. The combination of corticosteroids and cyclophosphamide is indicated for severe ocular disease [89]. Intralesional corticosteroid injections may produce short-term remission, but lack long-term benefits and even may induce cataract formation [90]. Topical corticosteroids are ineffective in controlling the progression of disease and should be avoided for treatment of acute relapses. Frequent lubrication with artificial tears is helpful, and the lids and conjunctiva should be controlled regularly to exclude bacterial infections.

Oral Lesions. Mild disease limited to the oral cavity may be initially managed with topical therapies and the occasional use of systemic corticosteroids during exacerbation [1, 2, 91]. Topical FK506 (tacrolimus) have also been shown to be of benefit, especially when used under dentures which facilitate application and provide an occlusive effect that increases potency [92, 93]. Local anesthetics (e.g. viscous lidocaine) used several times daily for rinsing the mouth may alleviate mouth pain and difficulties in swallowing [94]. In severe oral disease, oral corticosteroids together with dapsone or mycophenolate mofetil are needed [83, 88]. Careful mouth hygiene and avoidance of trauma is important to prevent infection.

Esophageal and laryngeal lesions. Systemic treatment with prednisone and cyclophosphamide is necessary for patients with severe esophageal or laryngotracheal lesions to prevent the serious complications of esophageal stenosis and asphyxiation [84].

Anogenital Lesions. Patients with anogenital lesions may require in most instances systemic corticosteroids. Major morbidity occurs when anogenital lesions result in scarring, and these patients should be treated systemically with the combination of prednisone and cyclophosphamide [84].

Cutaneous Lesions. Potent topical corticosteroids such as clobetasol may be of some benefit when applied to skin lesions. Intradermal corticosteroid injections can be performed in recalcitrant lesions of the skin; for example triamcinolone (5 mg/mL) applied every 2 to 4 weeks with a maximum of 40 mg [3]. Systemic corticosteroids or mycophenolate mofetil may be required in the treatment of localized skin lesions as well as for the control of generalized bullous eruptions [83].

Progressive mucous membrane pemphigoid

Given that there are no long-term studies confirming that anti-inflammatory or immunosuppressive agents delay the progression of disability, the treating physician must consider the patient’s individual risk of clinically significant early disability and the patient’s anticipated tolerance of treatment-related side effects. Indications for systemic therapy include progressive ocular, laryngeal or esophageal involvement and/or the presence of progressive oral or cutaneous disease unresponsive to less aggressive topical measures.

In a recent study in ten patients with progressive, otherwise treatment-resistant ocular pemphigoid, intravenous immunoglobulin (2 g/kg/month) therapy was shown to be an effective therapy, but data on the long-term efficacy and safety of this treatment modality are not yet available [95-97].

Control of treatment-related side effects

Cyclophosphamide is of great value in controlling both ocular and oral involvement but may provoke hemorrhagic cystitis, bone marrow suppression, infections, hair loss, sterility, amenorrhea, and the development of secondary malignancies (bladder carcinomas and lymphomas). The use of pulse cyclophosphamide in combination with corticosteroids, therefore, appears to be more appropriate [85].

Patients treated with azathioprine have an increased risk for bone marrow suppression with acute bone marrow failure, gastrointestinal diseases, liver damage, infections and lymphatic malignancies [98]. In general, treatment with azathioprine can be considered as safe; thiopurine methyl transferase serum activity should be determined prior to initiation of treatment to avoid severe side effects such as pancytopenia and hepatopathy.

Because of its lower toxicity profile and its selective mechanism of action, mycophenolate mofetil is a promising advance in the immunotherapy of mucous membrane pemphigoid. Myelosuppression, hepatotoxicity, or nephrotoxicity and minor signs of gastrointestinal intolerance may also occur. An increased incidence of bacterial or viral infections has not been demonstrated [83].

Major toxicities of dapsone include methemoglobinemia, hemolysis, leukopenia, hypersensitivity syndrome, hepatitis, nephrotoxicity, and peripheral neuropathy. Before onset of dapsone treatment, patients require a screening for their glucose-6-phosphatase dehydrogenase activity to prevent severe side effects [99].

Treatment of complications

Esophageal and laryngeal strictures may develop in patients with mucous membrane pemphigoid of the upper aerodigestive tract. In these cases dilation of the esophagus or resection of laryngeal stenosis becomes necessary. Tracheostomy may prevent asphyxiation in patients with severe tracheal involvement.

There are moderately effective treatments for several of the complications of genital mucous membrane pemphigoid. Surgery may occasionally be required for severe scarring involving the urethral or anal orifices. Sexual dysfunction and chronic pain are common and may respond to appropriate symptom-based treatment strategies.

Localized skin erosions on the scalp or face rarely respond to medication but can be healed permanently by full thickness skin grafts [104].

Challenges in basic research and future directions

Clinical trials should be designed to evaluate whether combinations of drugs with different mechanisms of action are more effective than single agent therapy and to identify promising agents as well as those that are toxic or ineffective. So far, most published studies are small (usually including fewer than twenty patients per group) and brief (less than three years of follow-up) and there is an urgent need to determine whether the currently approved, effective immunomodulatory therapies reduce the degree or delay the development of disability in patients with severe esophageal or ocular disease and progressive mucous membrane pemphigoid [82-84]. Although no controlled clinical trials have proven the usefulness of intravenous immunoglobulins, significant clinical experience supports this approach [95-97]. Other immunomodulatory approaches include inhibitors of pro-inflammatory cytokines, such as tumor necrosis factor-α. Two recent reports have demonstrated that the tumor necrosis factor-α inhibitor, etanercept, can be successfully applied in patients with mucous membrane pemphigoid [105, 106]. Other approaches focus on inhibiting the de novo-synthesis of pathogenic autoantibodies by depletion of peripheral B cells with the monoclonal anti-CD20 antibody, rituximab [107, 108].

Acknowledgements

Conflict of interest: none

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