ARTICLE
Auteur(s) :, Meral J Arin, Nicolas
Hunzelmann*
Department of Dermatology University of Cologne, 50924 Cologne,
Germany
accepté le 4 Mai 2005
Rituximab was the first monoclonal antibody that was approved for
the treatment of cancer in 1997. Since then, more than 300,000
patients with relapsed or refractory, low-grade or follicular
non-Hodgkin lymphoma (NHL) have been treated [1]. It has been shown
to prolong survival compared to chemotherapy alone and has been
widely adopted because of its activity and favourable toxicity
profile. Despite the absence of marketing authorization, rituximab
is used to treat various refractory autoimmune diseases. Idiopathic
thrombocytopenic purpura (ITP) was the first autoimmune disorder
that was successfully treated and there is also clear evidence of
efficacy in autoimmune haemolytic anaemia. Subsequently, rituximab
has been applied in rheumatoid arthritis [2], systemic lupus
erythematosus, myasthenia gravis, Wegener`s granulomatosis, Sjögren
syndrome and dermatomyositis. Skin involvement in these disorders
is often severe and is associated with remarkable morbidity.
Long-term remissions without further therapy have been observed in
patients with these disorders suggesting that immune tolerance may
be re-established.In pemphigus, B cell clones secreting
anti-desmoglein antibodies seem crucial in the development of the
disease. Initial studies in paraneoplastic pemphigus showed a
beneficial therapeutic depletion of B cells following rituximab [3,
4]. To date, several case series and open-label studies have been
conducted and suggest that rituximab has the potential to generate
long-term remission in cases refractory to standard
immunosuppressive therapy. In this review, we focus on the
extension of application of rituximab to autoimmune disorders, in
particular pemphigus and suggest that it is a promising addition to
the therapeutic armamentarium.
Rituximab – mode of action
B lymphocytes arising from haematopoietic stem cells progress
through a series of intermediate stages (pro-B, pre-B, immature B
and mature B cells) eventually differentiating into plasma cells,
which produce immunoglobulins. Rituximab is a genetically
engineered chimeric monoclonal antibody directed against the CD20
pan B cell glycoprotein that is expressed on pre-B cells, immature
B cells, naïve and memory B cells, but not on plasma cells [5].
CD20 is a transmembrane phosphoprotein that is involved in B cell
differentiation and activation. Its exact function is not known, it
has been suggested that it acts as a calcium channel subunit [6].
Elimination of CD20 in vivo does not seem to affect B cell
development since CD20 knockout mice have normal B cells [7].
Binding of CD20 does not modulate its expression and it is not shed
or secreted into the circulation [1]. After binding to CD20,
rituximab rapidly redistributes into a lipid raft, a cell membrane
fraction, that is involved in signal activation through tyrosine
kinases. Since these membrane changes are long-lived, they may also
be an explanation for late responses to rituximab therapy [8].
Since the murine CD20-binding Fab regions are retained and a
human Fc portion is used, the half-life of the antibody is
prolonged and with the human Fc a more effective complement
activation and attraction of cytotoxic cells can be achieved [9].
Presence of complement and its activation are important factors for
rituximab efficacy, but also seem to be related to the toxicity of
adverse reactions [10]. Several mechanisms have been demonstrated
by which rituximab depletes B cells, including complement
activation, antibody-dependent cytotoxicity, apoptosis induction,
and antiproliferative effects. It has been suggested that the key
event of rituximab action is binding to the Fc receptor which leads
to complement activation [11]. Three Fc receptor classes exist
(FcγRI, II and III) and polymorphisms are related to sensitivity to
infectious and autoimmune diseases [12]. Interestingly, the
response to rituximab was also associated with Fc receptor
polymorphisms and it was demonstrated that a dimorphism exists in
which residue 158 of FcγRIIIA can be either valine with higher
affinity to IgG or phenylalanine with weaker binding. These
polymorphisms correspond with differences in activation of
antibody-dependent cellular cytotoxicity by rituximab [13, 14]. The
importance of FcγRIIIA in rituximab activity was also demonstrated
in lupus patients with a diminished response to rituximab that were
shown to harbour a homozygous phenylalanine in position 158 [15].
These data suggest that the response to rituximab can be predicted
and has implications for the development of new antibody constructs
to overcome resistance.
Resistance to rituximab has also been attributed to either rapid
metabolism of rituximab due to alterations in host antibody
metabolism or high numbers of accessible CD20 molecules. Moreover,
anti-chimeric antibodies (HACA) which are directed against the
human Fc portion may play a role. It has been reported in less than
1% of patients with non-Hodgkin lymphoma thus being an uncommon
finding in clinical trials [16]. However, patients exist where the
development of HACA impairs the function of rituximab. Just
recently it was demonstrated in a patient with systemic lupus
erythematosus that in the presence of host antibodies against the
chimeric anti-CD20 antibody rituximab, a humanized monoclonal
anti-CD20 antibody (hCD20) can be effective [17]. This antibody is
currently in phase I trials for NHL and trials for autoimmune
diseases are planned.
Because CD20 is not expressed on stem cells and plasma cells,
depletion of the CD20 bearing B cell subpopulation is transient and
does not affect immunoglobulin synthesis. Usually, normal
peripheral B cells are replenished by hematopoetic stem cells in
most patients 3-12 months after therapy [18]. Depletion affects B
lymphocytes which are not secreting antibodies and it occurs in
every patient regardless of the clinical response. It could be
argued that after depletion of parent cells the antibody producing
plasma cells are not longer present, but this would not explain why
the immunoglobulin levels do not lower proportionally in some
patients despite clinical improvement. It has therefore been
suggested that long-lived plasma cells exist in the bone marrow
that secrete auto-antibodies and that the therapeutic effect is not
solely due to destruction of B cells. For instance, in rheumatoid
arthritis it has been postulated that the cross-talk between T and
B cells is a central event and autoreactive T cell clones depend on
antigen presentation by B lymphocytes to maintain their activation.
Therefore it was speculated that the removal of autoreactive B
lymphocytes induces the collapse of a vicious cycle in which
auto-antibodies drive their own production [19].
Current experience with the use of rituximab in autoimmune
diseases
Treatment of autoimmune disorders is still difficult since
long-term administration of corticosteroids, mostly in combination
with cytotoxic drugs, are the mainstay of therapy. Side-effects
either related to the non-specific action on the immune system or
to systemic pathogenic effects often limit their application [20].
The rationale for the use of rituximab in autoimmune disease is
long-term depletion of disease causing B cells. Its success in
antibody-mediated disorders such as idiopathic thrombocytopenic
purpura (ITP) and autoimmune haemolytic anaemia (table 1( Table 1 )) has further substantiated the
importance of auto-antibodies in the pathogenesis of autoimmune
diseases. In disorders where auto-antibody production is not
obviously the underlying pathogenetic factor, targeting of CD20
allowed to gain insights into the mechanisms that lead to the
development of autoimmunity. To date, various disorders such as
rheumatoid arthritis, myasthenia gravis, Wegener’s granulomatosis,
systemic lupus erythematosus, dermatomyositis, Sjögren syndrome,
multiple sclerosis, cold agglutinin disease, Goodpasture’s
syndrome, glomerulonephritis, antiphospholipid syndrome, and IgM
associated neuropathies have been treated with rituximab.
In haematological disorders such as autoimmune haemolytic
anaemia, mixed cryoglobulinaemia and idiopathic thrombocytopenic
purpura, overall response rates of up to 84% can be achieved (table
1). In ITP, the time to response varied widely between patients and
it was suggested that an early response might be due to rapid
activation of inhibitory receptors whereas a delayed response is
related to gradual elimination of auto-antibody producing cells
[21]. In patients with immune hemolytic anemia, ITP and myasthenia
gravis that were treated with rituximab the clinical improvement
has been reported to occur very rapidly, indicating that
elimination of B cells and subsequently a drop in the autoantibody
level cannot be the only explanation and that other factors
secondary to T cell de-regulation might play a role [22].
In patients with lupus erythematosus, a phase I/II open-label,
dose-escalating trial has been recently completed. Ten out of 16
patients treated with rituximab showed a good depletion of B cells.
Depletion persisted for 12 months and correlated well with the
clinical improvement [23]. Several cases of myasthenia gravis,
Wegener’s granulomatosis, Sjögren syndrome and dermatomyositis have
been reported that were treated with varying doses and schedules of
rituximab (table 1). Complete responses were demonstrated in about
half of the cases.
Most studies are open-label but recently a double-blind,
placebo-controlled trial has demonstrated the effectiveness of
rituximab in 161 patients with rheumatoid factor positive-
rheumatoid arthritis [2]. This study showed that all groups treated
with rituximab had a significantly higher proportion of patients
with a 20% reduction in disease symptoms. The combination of
rituximab with methotrexate was most effective, leading to a 50%
improvement of disease symptoms in 43% of the patients. The
majority of adverse events were infusion related, serious
infections occurred in four patients (3.3%) compared to 1 patient
in the control group (2.5%). A single course of two infusions of
rituximab showed a long-term improvement of the clinical disease
course and some patients were in remission one year after the last
infusion.
Table 1 Overview of autoimmune diseases treated with
rituximab
|
Disease
|
# of pts
|
Dosage and schedule
|
Response rate
|
Comment
|
Reference
|
|
ITP
|
203
|
4 × 375 mg/m2
|
44-73% OR
|
Largest study (n = 57)
|
[52]
|
|
TTP
|
24
|
4-5-8 × 375 mg/m2
|
21 CR, 2 PR, 1 NR
|
Largest case series (n = 5)
|
[53]
|
|
Red cell autoimmune disease (AIHA, CHD, RCA)
|
112
|
2-4 × 375 mg/m2
|
54-87% OR
|
Largest study CHD (n = 27)
|
[54]
|
|
Largest study AIHA (n = 15)
|
[46]
|
|
MC
|
39
|
4 × 375 mg/m2
|
Up to 80% CR
|
Largest study (n = 20)
|
[55]
|
|
Largest study (n = 15)
|
[56]
|
|
RA
|
234
|
|
- 50% improvement according to score (ACR)
- R: 33%, R+C: 41%, R+M: 43%
|
First double-blind, placebo-controlled study (n = 161)
|
[2]
|
|
SLE
|
60
|
2-4 × 375 mg/m2
|
64% improvement according to score (SLAM)
|
Phase I/II dose escalating trial (n = 17)
|
[23]
|
|
Myasthenia gravis
|
3
|
4 × 375 mg/m2
|
PR
|
Case reports
|
|
|
4 × 260 mg/m2
|
|
Wegener’s granulomatosis
|
3
|
4 × 375 mg/m2
|
CR
|
Case reports
|
|
|
Sjögren Syndrome
|
16
|
4-8 × 375 mg/m2
|
CR 9, PR 7
|
Case reports, retrospective study (n = 6)
|
|
|
Dermatomyositis
|
7
|
4 × 375 mg/m2
|
2 pts CR, 4 pts PR
|
Open-label study (n = 7)
|
[57]
|
Rituximab in refractory pemphigus
Pemphigus is a severe autoimmune blistering disorder that is
associated with increased morbidity and mortality. It manifests
with progressive blistering and erosions involving the skin and
mucosa. Three major subsets of pemphigus can be distinguished
according to clinical and histopathological features. Pemphigus
vulgaris patients commonly present with painful erosions and ulcers
of the oral mucosa. The disease course is typically severe and is
still associated with a mortality rate of 5-10%. Complications due
to sepsis and secondary to the use of high doses of corticosteroids
contribute to this high mortality rate [24]. Circulating
auto-antibodies target the desmosomal adhesion molecules,
desmoglein 1 and 3, which belong to the cadherin superfamily of
calcium-dependent adhesion proteins. These auto-antibodies have
been shown to be IgG4 and IgG1 subclasses in active disease but
only IgG1 in remission suggesting the former to be most pathogenic
[25]. Binding of these auto-antibodies leads to loss of cohesion
between neighbouring keratinocytes (acantholysis) and subsequent
blister formation [26]. Lesions in pemphigus foliaceus typically
occur on the skin and the mucous membranes are never affected.
Auto-antibodies only target desmoglein 1 which is expressed in the
superficial layers of the epidermis where there is no co-expression
of desmoglein 3. Paraneoplastic pemphigus develops in the context
of malignancies, most frequently lymphoproliferative disorders such
as non-Hodgkin lymphoma and chronic lymphatic leukaemia. The
mortality rate is very high with survival being the exception
rather than the rule. The cause of death in most cases is due to
sepsis, respiratory and multi-organ failure [24]. In addition to
desmoglein 1 and 3 antibodies, auto-antibodies in paraneoplastic
pemphigus are directed against members of the plakin family,
including desmoplakin, envoplakin, periplakin, plectin and bullous
pemphigoid antigen 1. Clinically, severe mucocutaneous involvement
with painful oral ulcers, polymorphous blistering, multiforme and
lichenoid skin lesions are seen.
Although the exact mechanisms are still unclear, B and T
lymphocytes and the interaction between these cell types are
involved in the pathogenesis. The critical role of auto-antibodies
produced by B cells stems from the observation that passive
transfer of anti-desmoglein 3 antibodies into newborn mice causes a
bullous disease resembling pemphigus [26, 27]. In addition, B cells
function as antigen-presenting cells and stimulate Dsg 3-specific
CD4+ T cells to secrete cytokines such as Il-4, IL-6 and IL-10
which are required for proliferation of memory B cells and
differentiation to antibody-producing plasma cells, respectively.
Recognition of distinct epitopes of the desmoglein molecule by T
cells seems therefore crucial for the initiation and maintenance of
auto-antibody production by B cells [28-30]. The concept of
self-perpetuating B cells with activation of T cells and generation
of plasma cells that secrete immunoglobulins capable of forming
immune complexes that promote survival of parent B cells was also
proposed in rheumatoid arthritis. By depleting B cells, not only
would the production of auto-antibodies be reduced but also the
“disease memory” be removed which is held in mutated immunoglobulin
genes in specific autoreactive clones [31]. The interplay between B
and T cells is further emphasized by the finding that in vitro
stimulation of peripheral blood mononuclear cells with Dsg3 does
not result in auto-antibody production when CD4+ T cells are
depleted [32].
Several case reports using rituximab in refractory or
life-threatening cases of pemphigus have been reported and showed
promising results (table 2)( Table 2 ).
The overall response rates were good with remissions lasting
several months. Treatment was well tolerated and adverse events
mainly consisted of infusion-related side effects such as nausea,
fever and chills. However, two case series of three patients each
reported serious infections such as pneumonia and septic arthritis
[33] and fatal pneumocystis carinii pneumonia [34]. An open-label
study of rituximab in five patients with refractory disease courses
of pemphigus vulgaris and pemphigus foliaceus has recently been
completed [35]. Significant B cell depletion in the peripheral
blood correlated with clinical improvement (assessed by the disease
activity score). However, the clinical improvement ( (figure 1) ) was not
accompanied by a decrease of auto-antibody titres in all patients
suggesting that auto-antibody producing plasma cells with longer
life spans exist. Previously, it was thought that auto-antibody
producing plasma cells are continuously generated. Recent data
indicate that plasma cells which are non dividing and have down
regulated B cell markers such as CD20, may reside in the bone
marrow for years [36-39]. This might explain persistent
auto-antibody and immunoglobulin levels such as anti-tetanus toxoid
IgG even with prolonged depletion of memory B cells using cytotoxic
agents or rituximab [40]. Moreover, different classes of
auto-antibodies may respond differently to cytotoxic agents. This
was recently suggested in patients with lupus erythematosus where
anti-dsDNA IgG were very responsive to treatment and disappeared
fast whereas antinuclear or anti-cardiolipin antibodies persisted
and remained elevated even in absence of overt clinical disease
[40]. Besides, auto-antibodies reactive with a broader range of
epitopes, also known as epitope spreading, may account for the lack
of antibody titre reduction in pemphigus, since these epitopes are
not differentiated by standard analysis of pemphigus antibody titre
[25, 41]. The pathogenic heterogeneity among anti-Dsg3 antibodies
due to their epitopes has been demonstrated in pemphigus vulgaris,
where antibodies directed against the amino terminus of desmoglein
3 are most pathogenic [42]. Thus, IgG4 directed against a
particular extracellular domain (EC2 domain) of desmoglein 3 is the
main acantholytic antibody while IgG4 against EC1 may act as a
facilitator or enhancer of this process [28]. Moreover, it has been
shown recently that in endemic pemphigus foliaceus (fogo selvagem)
the anti-desmoglein 1 response is initially raised against
nonpathogenic epitopes located in the EC5 domain whereas a
pathogenic response involves the EC1 and EC2 domains of the
molecule [43, 44].
The question why patients relapse has not been resolved. It is
possible that B cell clones have not been fully ablated or that
continued production of auto-antibodies by plasma cells provides
survival signals for re-emerging autoreactive B cells [45]. The
remission following rituximab usually lasts several months and
coincides with the drop of B cells. Recovery of B cells usually
begins at 6-9 months and the values return to normal after 9-12
months. Interestingly, one patient with pemphigus vulgaris has been
reported with a low CD 19 count three years after the last
application of rituximab which correlated well with clinical
remission [35]. Whether FcγRIIIA polymorphisms are the only
explanation for this finding remains to be elucidated.
Table 2 Overview of pemphigus patients treated with
rituximab to date
|
Disease
|
# of pts
|
Response rate
|
Duration of remission (mo)
|
Complications
|
Dosage
|
Comment
|
Reference
|
|
PV/PF
|
5
|
CR 3 pts
|
At 18, 24 and 36* mo no clinical disease
|
Infusion-related side effects
|
4 × 375 mg/m2
|
|
[35]
|
|
PR 2 pts
|
Minor disease at 10 mo
|
|
PV
|
3
|
CR 2 pts
|
18 mo, 4 mo (pt died)
|
Fatal PCP in one pt
|
4 × 375 mg/m2
|
|
[34]
|
|
PR 1 pt
|
Healing over 9 mo after 2nd course
|
|
2 × 4 × 375 mg/m2
|
|
PNP
|
1
|
PR
|
-
|
Death due to cardiac failure 9 mo after diagnosis of PNP
|
4 × 375 mg/m2 +2 × 4 × 375 mg/m2
|
NHL; pre existing cardiac disease
|
[58]
|
|
PV
|
1
|
CR
|
At 10 mo no clinical disease
|
Infusion-related side effects
|
4 × 375 mg/m2
|
|
[59]
|
|
PV
|
3
|
CR 2 pts
|
At 6 mo no clinical disease
|
Relapse of hip arthritis in 1 pt
|
1-2 × (4 × 375 mg/m2)
|
|
[33]
|
|
PR 1 pt
|
6 mo
|
Community acquired pneumonia
|
2 × (4 × 375 mg/m2)
|
|
PNP
|
1
|
PR
|
-
|
death 5 mo after diagnosis of PNP
|
8 × 375 mg/m2
|
Gastric B cell lymphoma
|
[60]
|
|
PF
|
1
|
CR
|
At 7 mo no clinical disease
|
Infusion-related side effects
|
4 × 375 mg/m2
|
|
[61]
|
|
PNP
|
1
|
Progression
|
-
|
Fatal sepsis
|
2 × 375 mg/m2
|
Walden-stroms macro-globulinemia
|
[62]
|
|
PV
|
1
|
CR
|
At 10 mo no clinical disease
|
No side effects
|
4 × 375 mg/m2
|
|
[63]
|
|
PV
|
1
|
CR
|
At 3 mo no clinical disease
|
No side effects reported
|
4 × 375 mg/m2
|
|
[41]
|
|
PV
|
1
|
CR
|
*same pt
|
No side effects
|
4 × 375 mg/m2
|
|
[64]
|
|
PV
|
1
|
PR
|
Minor disease at 20 mo
|
Sepsis
|
6 × 375 mg/m2
|
Concomitant C, IVIG
|
[36]
|
|
PNP
|
1
|
CR
|
At 12 mo no clinical disease
|
No side effects reported
|
4 × 375 mg/m2
|
NHL
|
[4]
|
|
PNP
|
1
|
PR
|
At 4 mo no clinical disease
|
No side effects
|
4 × 375 mg/m2 and 1 × 375 mg/m2 every 2
mo
|
NHL
|
[3]
|
Dosage and adverse reactions
Rituximab is administered by way of slow infusion over several
hours. The standard regimen consists of four infusions (= 1 course)
of rituximab with a dosage of 375 mg/cm2 at weekly
intervals. However, different protocols are used with two single
infusions [46] up to two courses [47] and dosages up to 1g
rituximab [2]. Pre-medication with an analgesic (such as
paracetamol), and antihistamine/ corticosteroid should be
performed.
Systemic infusion reactions are frequently observed in lymphoma
patients most probably due to a high load of abnormal B cells [48].
Approximately 50% of patients treated with rituximab experience
infusion-related adverse reactions, including cytokine release
syndrome. These are accompanied by hypotension and bronchospasm in
about 10% of patients. Severe cytokine release syndrome has been
reported to occur mostly in lymphoma patients, however a few cases
have been described that were treated for indications other than
lymphoma. A common feature was development of severe reactions
during the first infusion, particularly dyspnoe, severe
bronchospasm, and/or hypoxia [49]. In autoimmune diseases, these
adverse reactions seem less of a problem. A pricking sensation in
the throat that occurs 30 to 60 minutes after the start of the
infusion is a common feature and has been interpreted as
penetration of rituximab into the Waldeyer’s ring [45].
The absence of normal B cells for several months has not been
associated with a significant increase in infectious risk [16].
Total IgG levels and anti-tetanus titres are unaffected whereas IgM
levels are reduced to the lower end of the normal range [50]. In
patients with chronic lymphocytic leukaemia receiving fludarabine
and rituximab, the incidence of pneumocystis carinii pneumonia was
calculated 1-2%, reactivation of herpes simplex and varicella
zoster virus 5-10% whereas reactivation of cytomegalo virus seems a
rare event [51]. In patients with rheumatoid arthritis, there is
now some evidence that there is an increased risk of lower
respiratory infection [2].
In pemphigus patients treated with rituximab, treatment is
generally well tolerated, most adverse reactions occur during the
first infusion and consist of nausea, fever, chills, occasional
hypotension and dyspnoea. Usually, these reactions diminish with
subsequent infusions and can be well controlled by pre-medication
with paracetamol and antihistamines. However, single reports exist
in pemphigus patients that describe serious side effects, such as
pneumonia, septic arthritis [33] and fatal pneumocystis carinii
pneumonia [34].
Contraindications
Patients with liver or renal disorders, severe osteoporosis,
neurological and psychiatric disorders as well as pregnant and
lactating women should not receive rituximab. Since angina pectoris
and cardiac arrhythmias have occurred after treatment with
rituximab, patients with a history of cardiac disease should be
monitored closely. Patients with primary or secondary
immunodeficiency and a history of cancer are not eligible for
rituximab therapy. Active infections and a history of recurrent
clinically significant bacterial or viral infections are absolute
contraindications for rituximab therapy. Serological tests
including HBV, HCV and HIV should be performed prior to therapy.
Conclusions and outlook
Over 300,000 patients worldwide have been treated with rituximab
for various indications. Most data stem from studies conducted in
lymphoma patients and rituximab in combination with chemotherapy
seems promising. Several studies in different autoimmune disorders
now provide clear evidence of significant clinical benefit and it
is intriguing to speculate that the use of rituximab in severe
vasculitis associated with rheumatoid factor positive rheumatoid
arthritis, Wegener’s disease and mixed cryoglubulinaemia will be a
valuable addition to the current therapeutic options.
Clinical remissions are usually retained over several months,
sometimes prolonged responses are observed. The treatment is well
tolerated and infusion-related adverse events can be readily
controlled. Although infections do not seem to be a major problem
in autoimmune diseases, severe and fatal outcomes have been
reported. In case of relapse different protocols are used and often
a second course is applied. However, the long-lasting reduction of
circulating B cells in some patients raises the question of
long-term effects of repeated cycles on the complete maintenance of
the cellular and humoral immunity. New protocols using a reduced
dosage or a single infusion of rituximab in the case of relapse
have been used in some patients and might be sufficient to achieve
remission.
These data are based on small case series and should therefore
be interpreted with caution. Further controlled studies are needed
to optimise treatment regimes and to investigate the safety
profile. Whether rituximab will have its place as first-line
therapy in selected cases awaits further investigation.
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