Recent advances in understanding and managing IgG4-related disease

Introduction

IgG4-related disease is a recently described entity which is quite rare. Descriptions and recognition of the disease are advancing rapidly. Certainly, the fact that it closely resembles malignancy is one of the many reasons why recognizing this disease is important. Furthermore, it is generally very treatment-responsive, so early diagnosis can contribute to a significant improvement in morbidity for patients. The underlying disease mechanisms are an area of active research, and further understanding will aid in the treatment of patients.

Epidemiology

Because IgG4-related disease was only recently described and mimics other diseases, recognition remains low and a true estimation of prevalence remains elusive. In 2011, the prevalence of autoimmune pancreatitis in Japan was 4.6 per 100,000 population¹, but prevalence data for other organs involved in IgG4-related disease are not well characterized. In Japanese patients with autoimmune pancreatitis as well as Japanese patients with IgG4-related disease of other organ types², the patients are predominantly male; there are 3 to 4 males to every 1 female patient. The mean age in both studies was late 60s. In a cohort from Spain with IgG4-related disease, 69.1% of patients were male and the median age at diagnosis was 53 years³.

Interestingly, a recent review analyzed published pediatric cases of IgG4-related disease and found 25 cases with an average age of 13 and a mild female predominance (64%)⁴.

In one small cohort of 25 patients with IgG4-associated cholangitis and autoimmune pancreatitis, 88% reported a history of “blue collar” work, often with exposures to occupational chemicals⁵.

Clinical presentation

Patients classically present with subacute, non-specific complaints, which can be general, such as weight loss, or organ-specific complaints. The classic finding is a tumefactive lesion in at least one organ, but the disease can develop over years, adding new organs one at a time, so patients may present with multi-organ disease⁶. In the study by Chen et al., the mean number of organs involved was 3.0 ± 1.6 (range of 1–10)⁷. If the disease has progressed, organ failure can occur. Ruling out malignancy is crucial when the diagnosis of IgG4-related disease is considered. The differential is broad and is largely organ-specific, but multi-centric Castleman’s disease and other multi-organ autoimmune diseases such as granulomatosis with polyangiitis, Sjögren’s syndrome, eosinophilic granulomatosis with polyangiitis, and sarcoidosis should be considered.

Although the classic organ involved in IgG4-related disease is the pancreas, which presents classically with obstructive jaundice due to damage to the biliary tree, many organs can be involved (Figure 1). Recent novel reports of IgG4-related disease include disease involving the lung presenting with cough, dyspnea, chest pain, and fever⁸; involving the sinuses, which in some cases can be invasive^9–11; involving the esophagus presenting with dysphagia¹²; involving the prostate presenting with urinary retention¹³; or involving the testes presenting with scrotal pain¹⁴. Skin manifestations were rare in the series reported by Chen et al.⁷. A review of the dermatological literature showed that the most common skin presentations are papules, plaques, and nodules of the head and neck¹⁵. Clinical symptoms of patients were well summarized by Chen et al. (Table 1)⁷. Organ involvement from three case series is summarized in Table 2.

Figure 1. Many organs are involved in IgG4-related disease.

This figure shows diseases that have now been re-classified to be part of IgG4-related disease, including eponymous names.

Although most patients present before multi-organ involvement is evident, Higashioka et al. reported a case of a patient who had 10 organs involved in IgG4-related disease at the time of his diagnosis¹⁶.

The clinical presentation of IgG4-related disease often mimics a tumor, which can result in unnecessary surgical intervention. Surgical resection for presumed malignancies occurred in 18 out of 53 patients, about 34%, who were ultimately diagnosed with IgG4-associated cholangitis in the series reported by Ghazale et al.¹⁷. For example, Park and Kim¹⁸ and Wang et al.¹⁹ reported a case in which the discovery of a mass in the renal parenchyma resulted in a patient undergoing nephrectomy, and ultimately the mass was found to be IgG4-related disease. Similarly, Kim et al. presented a case of a patient in whom there was concern for cholangiocarcinoma and who underwent a left trisectionectomy but was ultimately diagnosed with IgG4-related disease²⁰. IgG4-related disease can also be initially mistaken for lymphoma, as both diseases can present with lymph node swelling as an initial symptom^21,22. Differentiating IgG4-related disease from cancer is of the utmost importance. The diagnosis of IgG4-related disease is ultimately reliant on diagnostic tools (Table 3).

Monitoring and following disease

Histopathology of IgG4-related disease

Histopathology is the gold standard for diagnosis of IgG4-related disease, since the disease cannot be diagnosed on the basis of IgG4 levels in the serum or in tissue samples on pathology, although these findings are suggestive of the disease. The classic findings are dense lymphoplasmacytic infiltrate, storiform fibrosis, and obliterative phlebitis (which means partial or complete obliteration of a vein)³⁸.The presence of at least two of these findings in combination with infiltration of IgG4-positive plasma cells is highly suggestive of a diagnosis of IgG4-related disease, with the cutoff value for the number of IgG4-positive plasma cells being defined for each organ. Eosinophils are commonly present. IgG4-positive plasma cells are distributed diffusely throughout the tissue, even in patients who have normal levels of serum IgG4. This finding can help to differentiate IgG4-related disease from other diseases characterized by plasma cell infiltration but is not sufficient to make the diagnosis. The cutoff value for the number of IgG4-positive plasma cells required to make a diagnosis is specific to the organ, but the ratio of IgG4 to IgG cells must be greater than 40%³⁸.

It is worth mentioning that the clinician must be cautious to not over-emphasize the role of histopathology, especially IgG4 immunostaining, when making a diagnosis of IgG4-related disease. Strehl et al. highlighted this nicely: they analyzed 121 randomly selected pathology specimens with lymphoplasmacytic infiltrates³⁹. Interestingly, variably high numbers of IgG4-positive plasma cells were found in diverse samples, particularly in rheumatoid synovitis, carcinoma-associated inflammation, and sclerosing sialadenitis³⁹. This article thus highlights the fact that IgG4 can be elevated in inflammation unrelated to IgG4-related disease³⁹. Cheuk and Chan also warned of the danger of over-interpretation of lymphadenopathy with positive immunostaining for IgG4 in a patient with no other clinical or laboratory signs of IgG4-related disease⁴⁰.

Treatment options

Mortality

In a recent systematic review of treatment of IgG4-related disease, Brito-Zeron et al. compiled the mortality data from 7 studies for 294 patients and a mean follow-up of 29.2 months⁴⁵. In this group, mortality was reported in 26 patients (8.8%). Four patients died of pulmonary disease, 1 died of an aneurysm, 1 of cholangitis, 1 of renal failure, 7 of cancer, 4 of cardiovascular disease, 3 of infection, and 5 of unknown or other causes⁴⁵.

Pathophysiology of IgG4

Genetics

There is much still to be learned about the genes involved in IgG4-related disease. Genetic susceptibility has been associated with certain human leukocyte antigen (HLA) haplotypes in Japanese and Korean populations⁴⁹. More recent studies have identified genes involved in pancreatic cell injury⁵², and cytotoxic T-lymphocyte antigen 4 (CTLA-4) gene polymorphisms have been associated with IgG4-related disease in the pancreas⁵³.

Autoimmunity

Autoimmunity has long been hypothesized as a pathologic mechanism in IgG4-related disease, but studies have failed to identify a clear autoantigen specific to the disease that selectively induces the production of IgG4 autoantibodies⁴⁹. It stands to reason that the target of the antibody would be specific to the organs commonly affected in IgG4-related disease. Indeed, a recent study which sought to identify autoantigens in IgG4-related disease identified only one candidate: prohibitin⁵⁴. As prohibitin is involved in anti-proliferation, the authors hypothesize that antibodies against prohibitin would result in tissue growth and the presentation of IgG4-related disease⁵⁴. Another recent study showed that anti-nuclear antibody (ANA) in IgG4-related disease was not of the IgG4 subclass⁵⁵. ANA was reported to be positive in 32% of patients (168 out of 524 patients)⁶.

Innate immunity

Evidence is beginning to accumulate that there is a role for innate immunity in the mechanism of IgG4-related disease. Nakajima et al. used DNA microarray analysis to show that the expression of genes associated with allergy or innate immunity is lower in the peripheral blood mononuclear cells of patients with IgG4-related disease compared with healthy controls (HCs) and that these levels were increased with steroid therapy⁵⁶. Furthermore, Watanabe et al. recently postulated that since activation of the innate immune system leads to the production of IgG4, this pathway could be the target of future treatments for IgG4-related disease⁵⁷.

Hypocomplementemia

A feature that is important in IgG4-related disease is hypocomplementemia. The etiology of this was studied by Sugimoto et al., who showed that patients with hypocomplementemia in IgG4-related disease have a high serum level of C1q-binding IgG4, thus implying that IgG4 participates in the activation of complement in these patients by an unknown mechanism⁵⁸.

Role of T cells (Th2, Treg, Tfh, and CD4⁺ CTL)

It has been observed that CD4 T cells are present at the sites of inflammation in IgG4-related disease. Similar to IgE, class switching to IgG4 depends on interleukin-4 (IL-4) and IL-13. These interleukins are considered part of the type 2 helper T (Th2) immune response. Messenger RNA levels of these Th2 cytokines are higher in organs affected by IgG4-related disease in comparison with other classic autoimmune conditions^59,60. The peripheral blood lymphocytes of patients with IgG4-related disease also express elevated levels of Th2 cytokines⁶⁰. A subset of patients also has elevated eosinophils and IgE, suggestive of an underlying disease mediated by Th2 cytokines.

Allergens and nematodes that induce IgE also induce IgG4. However, a so-called “modified Th2 response” refers to the scenario in which IgG4 antibody is produced without IgE antibody production, which seems to be the desired, healthy response to innocuous antigens, as it occurs during occupational exposures to antigens such as in beekeepers⁴⁸. Allergen-specific IgG4 antibodies are also induced during allergen immunotherapy and accompany clinical improvement⁶¹.

A role for elevated levels of regulatory T (Treg) cells in IgG4-related disease has also been suggested⁶². This is in contrast to most autoimmune conditions, in which a deficiency in Treg cells is present and thought to promote autoimmunity. In IgG4-related disease, it has been hypothesized that collagen deposition occurs through the production of cytokines produced by Th2 and Treg cells and thus that these cells could act synergistically to induce tissue fibrosis, a prominent feature of the disease⁶³.

Recent studies^64,65 suggest that the role of Th2 immune responses in IgG4-related disease may be overstated and may, in fact, be a reflection of atopy, which affects approximately 40%⁶⁶ of patients with IgG4-related disease, which is similar to the prevalence in the general US population. Instead, evidence is accumulating for a role of CD4-positive cytotoxic T lymphocytes (CTLs). Maehara et al. have shown over-expression of genes associated with CD4-positive CTLs in the salivary glands of patients with IgG4-related disease compared with HCs and compared with patients with Sjögren’s syndrome and chronic sialoadenitis⁶⁵. Furthermore, CD4-positive CTLs, which produce IL-1β, transforming growth factor-beta 1 (TGF-β1), and interferon-gamma (IFN-γ), are found in affected tissue. IL-1β and TGF-β1 have been shown to be involved in the pathology of fibrosis⁶⁷, an integral feature of IgG4-related disease, thus further strengthening the putative role of CD4-positive CTLs. Finally, rituximab-mediated B-cell depletion results in both clinical improvement of patients’ IgG4-related disease and a decrease in the number of CD4-positive CTLs⁶⁴. This new research is exciting, as CD4-positive CTLs may ultimately prove to be the major mechanism of pathogenesis of IgG4-related disease.

The role of circulating follicular helper T (Tfh) cells in IgG4-related disease is an active area of research. Akiyama et al. have published two articles implicating a role for these cells in IgG4-related disease^68,69. They showed that in patients with untreated IgG4-RD compared with those with primary Sjögren’s syndrome, those with multi-centric Castleman’s disease, and HCs, the number of circulating Tfh2 cells (defined as CD3⁺CD4⁺CD45RA⁻CXCR5⁺CXCR3⁻CCR6⁻) was significantly increased. Furthermore, “activated” Tfh2 cells (defined by the additional markers CCR7^lowPD-1^high) were shown to induce IgG4 production and to decrease in response to treatment with glucocorticoids in parallel with decreased disease activity⁶⁸. Activated circulating Tfh1 cells were also found to correlate with disease activity but not with serum IgG4 levels⁶⁸.

Pathogenic effects of B cells and IgG4

Maillette de Buy Wenniger et al. showed that IgG4-positive B cells were clonally expanded in patients with IgG4-associated cholangitis and decreased when the patients were treated with glucocorticoids⁷⁰. The role of the B cells in IgG4-related disease is especially interesting given the utility of rituximab-mediated CD20⁺ B-cell depletion in treating these patients⁴⁶. Recent studies have shown that circulating plasmablasts are increased in patients with IgG4-related disease and that their levels reflect disease activity^30,31. The plasmablasts are oligoclonal, which suggests that specific antigen(s) may be driving their production³⁰. In B-cell development, plasmablast differentiation occurs between activated B cells and plasma cells.

Role of M2 macrophages and MARCO

Returning to the issue of the IgG4-related disease being mainly a Th2-mediated disease, a possible disease mechanism could be mediated by M2 macrophages, which are defined as alternatively activated macrophages stimulated by Th2 response. IL-10, IL-13, and CCL18 produced by M2 macrophages induce fibrosis, and a recent study⁷¹ showed that there are increased numbers of M2 macrophages in submandibular glands affected by IgG4-related dacryoadenitis and sialoadenitis and that fibrosis is associated with an increased number of M2 macrophages. Macrophage receptor with collagenous structure (MARCO) is a pattern-recognition receptor with an expression pattern similar to that of the M2 macrophage marker CD163. It has been speculated that MARCO may be involved in the initiation of IgG4-related disease⁷². Future research is needed to ascertain whether there is any interaction between CD4-positive CTL or Th2 Tfh cells and M2 macrophages in promoting IgG4-related disease.

Conclusions

IgG4-related disease, though uncommon, is an important disease entity to consider in the differential of a patient presenting with tumefactive lesions. Current research into the underlying pathophysiology is focused on improved understanding of the T-cell and B-cell compartments. Future studies to improve the prognosis of this condition will focus not only on arresting the abnormal immunologic response but also on treating fibrosis.