Immunoglobulin and free light chain abnormalities in Gaucher disease type I: data from an adult cohort of 63 patients and review of the literature.

Gaucher disease type I, the most common lysosomal storage disorder, is associated with immunoglobulin abnormalities. We studied the prevalence, risk factors, pathogenesis, and effect of enzyme relation therapy (ERT) on gammopathies in an adult Gaucher disease type I cohort (N = 63) and related the results to a review of the currently available literature. Polyclonal gammopathies and monoclonal gammopathy of undetermined significance (MGUS) in our adult GD I cohort were found in 41% and 19% of patients. These results are similar to the data from the literature and correspond to the increased risk of multiple myeloma (MM) that has been described. The prevalence of MGUS in our cohort increased with age but was not associated with disease severity or exposure time. The serum levels of free light chains of immunoglobulins were measured and were not found predictive for the development of MGUS or MM. Levels of pro- as well as anti-inflammatory cytokines, growth factors, and chemokines, especially those involved in inflammation and B-cell function, are disturbed in GD I, with the most impressive and consisting elevations for interleukin-10 and pulmonary and activation-regulated chemokine. A beneficial effect of ERT on the occurrence and progression of gammopathies was suggested from longitudinal data.

Introduction

Gaucher disease type I (GD I, OMIM #230800) is the most common lysosomal storage disorder. The disease is characterized by a deficiency of the lysosomal enzyme glucocerebrosidase (glucosylceramidase), which leads to the accumulation of glucocerebroside in macrophages. The lipid laden macrophages are called Gaucher cells and are mainly found in liver, spleen, and bone marrow, resulting in the most important clinical features hepatosplenomegaly, skeletal disease, and cytopenia [1, 2]. Since 1991, GD I can be effectively treated with recombinant glucocerebrosidase (enzyme replacement therapy, ERT, imiglucerase; Genzyme, Cambridge, MA, USA). More recently, substrate reduction therapy (miglustat, Actelion Pharmaceuticals, Basel, Switzerland) has been registered for more attenuated disease.

An associated feature of GD I is the high frequency of polyclonal and monoclonal gammopathies [3-22]. In the general population, polyclonal hypergammaglobulinemia is a common clinical finding, especially in the setting of chronic inflammation [23], resulting from an overproduction of immunoglobulins by plasma cells or B-lymphocytes. An abnormal increase of monoclonal immunoglobulins or fragments thereof (M protein) can be found in pre-malignant conditions such as MGUS (monoclonal gammopathy of undetermined significance) and malignancies of the B-cell lineage such as multiple myeloma (MM), primary amyloidosis, Waldenström macroglobulinemia, chronic lymphocytic leukemia, and B-cell lymphoma. MGUS is found in approximately 3.2% of adults over the age of 50, increasing to 7.5% at the age of 85 [24]. Of these individuals, 1% per year shows progression to MM or a related malignancy. Accordingly, in GD I the risk of MM is strongly increased, as has been reported in recent studies [25-29]. The risk increases with advancing age [19, 26], but whether disease severity is a risk factor is currently unknown.

The mechanism explaining the relationship between GD and immunoglobulin abnormalities is far from understood. Studies have mainly focused on cytokines as the mediators between Gaucher cells, surrounding macrophages and B cells. Plasma levels of several pro-inflammatory cytokines, such as tumor necrosis factor (TNF)-α, interleukin (IL)-1, and IL-6, as well as the anti-inflammatory IL-10, were found to be increased in GD to variable extents [4, 30–33]. IL-6 and IL-10, as well as hepatocyte growth factor (HGF), are also involved in the pathogenesis of MM [34]. Other interesting factors, known to be highly elevated in GD patients, are pulmonary and activation-regulated chemokine (PARC) [35], which is involved in initiating the adaptive immune response. Two studies have reported on the effect of ERT, with some decrease in polyclonal gammopathies [6] and a decline in monoclonal M-protein level in a single case [36].

A relatively new method to identify and monitor monoclonal gammopathies is by quantifying immunoglobulin free light chains (FLC), circulating κ and λ chains that are not bound to the immunoglobulin heavy chains, using a highly sensitive automated immunoassay [37-39]. An abnormal FLC ratio is an important independent risk factor for progression of MGUS to MM or a related disorder [40, 41]. In addition, measuring FLC is a sensitive additional tool to identify monoclonal gammopathies [42]. In GD I, in which the incidence of MGUS and MM is highly increased [26], the FLC assay may provide a useful diagnostic tool for early detection of MGUS and MM.

In this study, we present new data on the prevalence of polyclonal and monoclonal gammopathies from a large adult GD I cohort and review the currently available literature. Second, we studied whether age, disease severity, and exposure time are risk factors for the development of monoclonal gammopathies, and if this risk is subsequently decreased by the administration of ERT. In addition, for the first time, we investigated the role of FLC as a predictor of the development of monoclonal gammopathies in GD I. Finally, the pathogenesis of immunoglobulin abnormalities in GD patients was studied by means of pro- and anti-inflammatory cytokine, chemokine, and growth factor levels and is discussed in relation to previous literature.

Materials and methods

Patients and study design

The files were reviewed and archived serum samples were collected of all adult GD type I patients that were known from the outpatient clinic for inherited metabolic disorders at the Academic Medical Centre (AMC), Amsterdam, The Netherlands (N = 63). The diagnosis GD was based on measurement of deficient glucocerebrosidase activity in leukocytes and genotyping [43]. Of the 63 patients, 50 received ERT according to an individualized dosing protocol [44] and two patients received substrate reduction therapy. Data on age, sex, splenectomy, genotype, severity score index, (SSI [45]), creatinine, urea, chitotriosidase, and the presence and type of immunoglobulin class of monoclonal proteins were collected. In patients with a monoclonal gammopathy, exposure time was defined as the number of years between the diagnosis GD I and the diagnosis monoclonal gammopathy or start of ERT, whichever came first. In patients without a monoclonal gammopathy, exposure time was calculated as the number of years between the diagnosis GD I and start of therapy, or, in patients not receiving therapy, the first visit to our clinic.

MGUS was defined as the presence of a monoclonal immunoglobulin component in the serum (as determined by protein electrophoresis in agar/agarose gels and immunofixation) at a concentration of less than 30 g/l (IgG, IgA, or IgM) and normal serum calcium and creatinine [46]. Although histology is required to distinguish osteolytic lesions caused by MM from those caused by GD, we decided to classify long-existing lesions as being GD related. Bone marrow examinations were only performed when a previously unknown M protein was discovered or in case of a sharp rise in the levels of immunoglobulins or FLC. In case of MM, stage was determined according to the Durie–Salmon [47] and International Staging System (ISS) criteria [48].

We investigated whether levels of FLC could be predictive for the development of MGUS and whether these levels were related to disease severity. Therefore, we measured FLC levels in serum before start of enzyme replacement therapy in ten patients with mild GD (SSI ≤ 8) and ten patients with severe GD (SSI ≥ 9), all without a monoclonal gammopathy.

In addition, we studied whether changes in cytokine levels and in FLC and immunoglobulins at baseline and during ERT were related to the presence or absence of a monoclonal gammopathy. Therefore, the group of patients with a monoclonal gammopathy was matched for age, sex, spleen status, SSI, and the use of ERT to a control group of GD patients without a monoclonal gammopathy. Serial measurements of levels of IL-6, IL-10, and PARC at baseline and after 12, 24, and a median of 114 months of ERT (range 40–143, whatever was the last determination) were performed. These were related to changes in immunoglobulins and free light chains. Hepatocyte growth factor (HGF) was measured only at baseline. One patient did not receive therapy; the first hospital visit was used as T0.

Assays

The standard enzyme activity assay for chitotriosidase with 4-MU-chitotriose (Sigma, St. Louis, MO, USA) as a substrate was performed at pH 5.2 [49]. Serum κ and λ FLC were measured using FREELITE reagents (The Binding Site Ltd, Birmingham, England) on a BNII nephelometer (Dade-Behring, Deerfield, IL, USA) [37-39]. Monoclonal FLC were identified as values for κ or λ that exceeded the reference ranges (κ 6.2–30.2 mg/l, λ 9.1–40 mg/l) and produced an abnormal κ/λ ratio (<0.3 or >1.57). Elevated concentrations of FLC without an abnormal κ/λ ratio indicate a polyclonal or oligoclonal increase of FLC. Levels of IgG, IgA, and IgM were measured by immunoturbidimetric assay (Roche Tina-quant). IL-6, IL-10, HGF, and PARC were measured by specific enzyme-linked immunosorbent assays (ELISAs), according to the instructions of the manufacturer (IL-6 and IL-10: Sanquin, Amsterdam, The Netherlands; HGF: R&D Systems, Minneapolis, MN, USA; PARC: Biosource International, Camarillo, CA, USA).

Statistics

Values in patients are given as medians and ranges. Differences between patient groups were analyzed by the Mann–Whitney U test or by χ-square test. Linear mixed models were used to assess longitudinal changes. Correlations were tested by the rank-correlation test (Spearman coefficient, ρ). P < 0.05 was considered to represent a statistical difference.

Search strategy

To compare the prevalence of poly- and monoclonal gammopathies in our cohort with earlier case series and to study the relative risk of MM, we performed a MEDLINE search combining the MESH terms Gaucher disease with either hypergammaglobulinemia, paraproteinemias, and/or multiple myeloma. Literature on cytokines, chemokines, and growth factors in relation to the development of immunoglobulin abnormalities in GD were searched combining the MESH terms Gaucher disease with cytokines and/or chemokines. Case reports were excluded and only studies that included at least ten patients were selected.

Results

Patients

The 63 patients had a median age of 53 years (range 25–83). Thirty-two of patients (51%) were men, and 23 (37%) were splenectomized. At baseline, median SSI was 8 (range 3–19). The majority of patients had a genotype containing N370S (95%), with N370S/L444P being the most common combination (40%). All patients had creatinine and urea values within the normal range.

At the first assessment, 24 (38%) patients had normal immunoglobulin levels, 26 (41%) patients had a polyclonal gammopathy, 12 (19%) patients had MGUS, and one patient had MM (Table 1, #2). During follow-up (range 5–16 years), none of the patients with normal immunoglobulin levels or a polyclonal gammopathy developed a monoclonal gammopathy.

Table 1

Characteristics of Gaucher disease type I patients with a monoclonal gammopathy

Patient no.	Sex	Sx	Age in 2007 or at death	Therapy	MG type	Ig type
1	M	N	55	ERT	MGUS, progression to amyloidosis and MM	Free κ
2	M	Y	71	ERT	MM	IgGκ
3	F	N	46	ERT	MGUS, progression to amyloidosis	IgGλ
4	M	Y	60	ERT	MGUS	IgGκ
5	M	Y	67	ERT	MGUS	IgGλ
6	M	Y	59	ERT	MGUS	IgAλ, IgGκ
7	F	N	67	ERT	MGUS	IgAκ
8	M	N	56	ERT	MGUS	IgGλ
9	M	Y	65	ERT	MGUS	IgGκ, IgGλ, IgAκ
10	M	N	56	ERT	MGUS	IgMκ, IgMλ
11	F	N	63	No	MGUS	IgGλ, IgMκ
12	F	Y	75	ERT	MGUS	IgGκ
13	M	N	51	ERT	MGUS	IgGλ

M Male, F female, Sx splenectomy, ERT enzyme replacement therapy, MG monoclonal gammopathy, MM multiple myeloma, MGUS monoclonal gammopathy of undetermined significance, Ig immunoglobulin

Of the 12 patients with MGUS, two developed MM and/or amyloidosis after approximately 2 years of ERT (#1 and 3). Patient #1 was diagnosed with MM and amyloidosis 25 months after start of ERT. Pulse therapy with dexamethasone was started. Three months after the diagnosis the patient died from cardiac failure. At 24 months after start of ERT, patient #3 was diagnosed with amyloidosis. She received melphalan and prednisone, but died 12 months later from cardiac failure. Patient #2 was diagnosed with MM stage IA before start of ERT. During follow-up, IgG levels gradually increased. After 7 years of ERT, treatment with reduced dose melphalan and prednisone was started, which resulted in unacceptable cytopenia. Subsequently, thalidomide, 100 mg daily, was started with beneficial effect and stable disease parameters for the last 3 years.

Of the ten remaining patients with non-progressive MGUS, six had a monoclonal, three had a biclonal, and one a triclonal gammopathy. The most common immunoglobulin type was IgGκ (Table 1; results previously presented in part in [26]).

Patients with a monoclonal gammopathy were significantly older than patients without a monoclonal gammopathy (Table 2). Exposure time to GD, defined as time from diagnosis until first assessment at our clinic, and severity of disease measures, assessed by SSI and chitotriosidase at baseline, were comparable.

Table 2

Baseline characteristics of Gaucher type I patients with a monoclonal gammopathy vs patients without a monoclonal gammopathy

	Without MG	With MG	P
No. of patients	50	13
Age in 2007 or at death	51 (25–83)	60 (46–75)	0.003
No. of male patients	23 (46%)	9 (69%)	NS
Years of exposure	11 (0–37)	18 (1–44)	NS
No. of splenectomies	17 (34%)	6 (46%)	NS
SSI at baseline	7 (3–19)	12 (4–16)	NS
Chitotriosidase (nmol/ml h) at baseline	16,703 (5,409–132,199)	22,534 (6,417–62,122)	NS

Data reflect absolute numbers (and percentage) or median (and range).

MG Monoclonal gammopathy, NS not significant, SSI severity score index

A search for studies on monoclonal and polyclonal gammopathies in GD I resulted in five series [4, 6, 16, 19, 21]. Polyclonal gammopathies were reported in 14–64% and monoclonal gammopathies in 1–35% of GD I patients (Table 3).

Table 3

Studies on the prevalence of monoclonal and polyclonal gammopathies in type I Gaucher disease

Reference	No. of Gaucher patients	Age	Polyclonal gammopathies	Monoclonal gammopathies
de Fost et al. [26]	63	25–83	26 (41%)	12 (19%)
Pratt et al. [19]	16	9–70	6 (38%)	4 (25%)
Shoenfeld et al. [21]	25	24–78	15 (60%)	2 (8%)
Marti et al. [16]	23	41.8 ± 18	10 (43%)	8 (35%)
Allen et al. [4]	22	23–65	14 (64%)	3 (14%)
Brautbar et al. [6]	507	16–81	14–25%	5 (1%)

Data reflect absolute numbers (and percentage), or, in the study of Marti et al., mean ± standard deviation.

Five studies have described the prevalence and/or relative risk of MM in GD patients [25-29]. Table 4 summarizes the data from these studies. The frequency of MM in these cohorts was 0.4–4.0%, with significantly elevated relative risks of 5.9–51.1.

Table 4

Studies on the prevalence and relative risk of multiple myeloma in type I Gaucher disease

Reference	No. of patients	Ethnic background	Age	Control group	No. of patients with MM	RR of MM
de Fost et al. [26]	131	Mixed	50 ± 14	Dutch Cancer Registry	2 (1.5%)	51.1 (95% CI: 6.2–184)
Lee [25]	239	Mixed	Not given	None	5 (2%)	ND
Shiran et al. [28]	48	Jewish	54 ± 20	511 individuals from the same region	2 (4%)	ND
Zimran et al. [29]	505	Jewish	38 ± 21	Israeli Cancer Registry	2 (0.4%)	ND
Rosenbloom et al. [27]	2,510	Mixed	33	US Cancer Registry	10 (0.4%)	5.9 (95% CI: 2.8–10.8)

Data on age reflect mean ± standard deviation; data on number of patients with multiple myeloma reflect absolute numbers (and percentage).

MM Multiple myeloma, RR relative risk, 95% CI 95% confidence interval, ND not done

Immunoglobulin and FLC levels

In 20 GD patients from the Dutch cohort without a monoclonal gammopathy (ten with mild disease, SSI ≤ 8, and ten with severe disease, SSI ≥ 9), FLC were measured before start of therapy (Fig. 1a). One patient was found to have a slightly abnormal ratio, and six patients had an increase in one or both FLC, with a normal ratio. There were no significant differences in κ or λ FLC-levels between patients with severe- and patients with mild GD I. During follow-up (range 10–16 years), none of the patients developed a monoclonal gammopathy.

Fig. 1

FLC levels in Gaucher disease type I patients without a monoclonal gammopathy with mild disease (SSI ≤ 8) and severe disease (SSI ≥ 9) (a). FLC levels in Gaucher disease patients with a monoclonal gammopathy and matched Gaucher disease controls (b). MG Monoclonal gammopathy. The normal range for κ was 6.2–30.2 mg/l and for λ was 9.1–40 mg/l. The normal ratio for κ/λ was 0.3–1.57

FLC levels were measured in all GD I patients with a monoclonal gammopathy (Table 1, #1–13) and matched GD I controls (#co1–co13). No serum was available of patient #12, resulting in two groups of 12 patients. Baseline immunoglobulin levels were not available in one patient with a monoclonal gammopathy (#11) and five patients from the control group (#co4, #co5, #co7, #co11, and #co13). At baseline, the patients who already had or would develop MM and/or amyloidosis (#1–3) had strongly abnormal FLC κ/λ ratios (Fig. 1b). Of the nine patients with MGUS, one (#7) had an abnormal FLC κ/λ ratio and four showed elevated levels of FLC κ or λ, but with a normal FLC ratio. The remaining four patients with MGUS had both FLC levels as well as a FLC κ/λ ratio within the normal range. Six of the patients from the control group had FLC levels and a FLC κ/λ ratio within the normal range, and six had elevated levels of one or both chains of whom only one (#co6) patient showed an abnormal FLC κ/λ ratio. During follow-up (range 6–15 years), none of the patients from the control group developed a monoclonal gammopathy.

Cytokines, chemokines, and growth factors

At baseline, IL-6 levels were within the normal range in all but four patients (Fig. 2). There was no significant difference in IL-6 levels between patients with or without a monoclonal gammopathy (median (range) 5.9 pg/ml (1.2–118.4) and 2.2 pg/ml (1.0–57.2), respectively). The majority of patients (17/24) showed elevated IL-10 levels, especially in the group of patients with a monoclonal gammopathy, although not significantly different from the patients without a monoclonal gammopathy (17.1 pg/ml (3.9–419.8) and 6.9 pg/ml (1.4–299.3), respectively, P = 0.2). PARC levels were elevated in all GD patients, without a difference between patients with or without a monoclonal gammopathy (1,400.0 pg/ml (348.9–2817.3) and 1,078 pg/ml (411.4–3,552.0), respectively). HGF was within the normal range in most (16/22) patients, without a difference between patients with or without a monoclonal gammopathy (1,751 pg/ml (926–4,791) and 936 pg/ml (424–9,382), respectively).

Fig. 2

Baseline levels of IL-6, IL-10, PARC, and HGF in Gaucher disease patients with a monoclonal gammopathy and matched Gaucher disease controls. Patients with multiple myeloma and/or amyloidosis are marked by an arrow. Dotted lines reflect the upper limit of the normal range. IL Interleukin, HGF hepatocyte growth factor, PARC pulmonary and activation-regulated chemokine, MG monoclonal gammopathy

A literature search resulted in seven studies on cytokines, chemokines, and growth factors in GD I patients (Table 5). In one of these studies, mRNA levels were measured [32], while in the remaining studies, plasma levels were studied. If possible, the number of patients with cytokine levels exceeding the reference range was determined. In studies in which normal ranges were not provided [4, 32], we defined the normal range as mean ± 2SD based on the values of the control group. This was not possible in the study of Barak et al. [30], in which no detailed data were provided.

Table 5

Studies on plasma levels of cytokines, chemokines, and growth factors in Gaucher type I patients

Reference	No. of GD I patients	Age	Cytokines	Results, no. of patients (%) with elevated levels	P value for difference with mean values of the control group
de Fost et al. [26]	22	25–83	IL-6	4/24 (17%)	ND
			IL-10	17/24 (71%)
			PARC	24/24 (100%)
			HGF	6/22 (27%)
Michelakakis [33]	25	NG	TNF-α	16/25 (64%)	ND
Allen et al. [4]	22	23–65	IL-1β	Not detectable	NS
			TNF-α	4/11 (36%)	NS
			IL-6	19/22 (86%)	P = 0.0001
			IL-10	13/13 (100%)	P < 0.0001
Lichtenstein et al. [32]	18	NG	IL-1β mRNA	5/19 (26%)	P = 0.0337
			TNF-α mRNA	2/19 (11%)	NS
			IL-6 mRNA	3/19 (16%)	NS
			IL-8 mRNA	3/19 (16%)	NS
Hollak et al. [31]	29	16–66	M-CSF	24/28 (86%)	P < 0.001
			sCD14	25/27 (93%)	P < 0.0005
			IL-8	25/27 (93%)	P < 0.0005
			IL-6	0/27 (0%)	NS
			TNF-α	0/27 (0%)	NS
Barak et al. [30]	21	5–39	IL-1β	Mean levels elevated	P = 0.01
			IL-1RA	Mean levels elevated	P = 0.01
			sIL-2R	Mean levels elevated	P < 0.001
			IL-6	Mean levels elevated	P < 0.01
			IL-8	Not elevated	NS
			TNF-α	3/21 (14%)	NS
Boot et al. [35]	55	12–67	PARC	55/55 (100%)	P < 0.0001
Altarescu et al. [56]	12	11–67	TNF-α	1/12 (8%)	NS

NG Not given, ND not done, NS not significant

Longitudinal changes

In general, at no time point was there a statistically significant difference in plasma levels of any of the factors (i.e., IgG, IgA, IgM, FLC κ and λ, IL-6, IL-10, and PARC) between patients with and patients without a monoclonal gammopathy (Fig. 3). In addition, using mixed model analysis, in neither of the two patient groups, a significant decrease or increase could be established in plasma levels of any of the measured factors. The only exception was PARC, which decreased in all patients, except for one patient who did not use therapy (#11). Changes in PARC levels could not be related to changes in levels of immunoglobulins or free light chains. There were no strong correlations (i.e., rho > 0.6) between any of the factors.

Fig. 3

Longitudinal changes in plasma levels of immunoglobulin heavy and free light chains, IL-6, IL-10, and PARC. Dotted lines reflect the normal range. Numbers reflect Gaucher disease patients with a monoclonal gammopathy as described in Table 1 (#1–13) and matched Gaucher disease controls (#co1–co13) without a monoclonal gammopathy. IL Interleukin, PARC pulmonary and activation-regulated chemokine

More specifically, immunoglobulin levels remained stable or decreased in all patients, except for patient #11, who showed an increase in IgM. This patient was different from other MGUS patients because she did not receive therapy. Free light chain levels were more variable, but clearly FLC levels of patients who were to develop or already suffered from MM and/or amyloidosis remained high during ERT (#1–3). Although in most patients no trends could be distinguished, a consistent decrease in free light chains and immunogobulins was seen for example in patient 7, who had an IgAκ M protein. This patient responded very well to ERT, but other patients with excellent clinical responses did not always show a similar decrease in M-protein levels. No relationship was found between clinical response and decrease in either levels of immunoglobulins or FLCs.

The course of cytokines did not show a relationship with changes in either FLC or immunoglobulin levels, although in the untreated patient with increasing levels of IgM (#11), also an increase in IL-6 and PARC was noted. On the contrary, a spontaneous decrease in IL-6 was found in patient #2, without therapy for his MM. In patient #1, IL-10 showed a clear decrease after start of ERT but before the diagnosis amyloidosis and MM was made.

Discussion

In addition to the classical symptoms of GD I, such as hepatosplenomegaly, skeletal disease, and cytopenia, there is increasing evidence for existence of co-morbidities, including increased risk of cancer and abnormal immunoglobulin profiles. In fact, polyclonal gammopathies and MGUS occurred in 41% and 19%, respectively, of our adult Gaucher cohort, which is in line with findings from the literature (14–64% and 1–35% of patients [4, 6, 16, 19, 21]). In addition, we established that the relative number of biclonal (3/10) and triclonal (1/10) gammopathies within the MGUS patients was especially high considering that in general, biclonal gammopathies occur in 3% of subjects with MGUS [24], while triclonal gammopathies occur only very sporadically [50]. The types of immunoglobulin heavy and light chain immunoglobulins were comparable to the findings for MGUS in a non-GD population, with a predominance of IgGκ [24]. As in the general population, the prevalence of MGUS in our cohort increased with age, but there was no relationship with disease severity measures, as assessed by exposure time, baseline SSI, and chitotriosidase levels. A relationship with age was first suggested by Pratt et al. [19], who investigated 16 patients aged 9 to 70 years and established an MGUS in four patients, all being over 50 years of age. Indirectly, he also showed an association with severity of disease, since all patients with splenomegaly had either a monoclonal or polyclonal gammopathy.

Considering the relatively high risk of monoclonal gammopathies in GD, the question was raised whether sensitive measuring of FLC would be useful for the early detection of monoclonal gammopathies in GD I patients. In a non-GD population, MGUS patients showed an abnormal FLC ratio in 44% of cases, which was an important risk factor for progression to MM or a related disorder [40, 41]. We found that the three GD patients who had or would soon develop a B-cell malignancy could easily be identified by their strongly abnormal FLC κ/λ ratios. It was however, not possible to identify GD patients with MGUS on the basis of abnormal FLCs since 44% of GD patients with MGUS had both FLC levels as well as a FLC κ/λ ratio within the normal range. A slightly abnormal ratio was not predictive for progression to MM or MGUS in the single patient without a monoclonal gammopathy, even after 15 years of follow-up. None of the patients had a decrease in renal function, implicating that any FLC increase was indeed due to increased production by plasma cells.

MGUS patients are at risk for developing MM at a rate of 1% of patients per year. Accordingly, the prevalence of MM in GD I cohorts of 0.4–1.5% clearly exceeds the general prevalence of 0.02% (deduced from The Surveillance, Epidemiology, and End Results (SEER) Program of the National Cancer Institute (NCI)). The assumed diversity in relative risk of developing MM (5.9 and 51.1) can simply be explained by age differences in the cohorts: the highest number of MM patients was clearly established in the highest age groups.

In a recent consensus report on hematological manifestations of Gaucher disease, the higher incidence of multiple myeloma in Gaucher disease is acknowledged, and it is recommended that Gaucher patients should have their immunoglobulin profile determined at diagnosis and monitored every 2 years (patients <50 years) or every year (patients >50 years) [51].

Hypotheses on the pathogenesis of immunoglobulin disorders in GD have mainly focused on the accumulated glucocerebroside as the causative agent for chronic stimulation of macrophages surrounding Gaucher cells. Cytokines of macrophagic origin could in turn stimulate B cells, leading to a polyclonal gammopathy which may eventually transform, directly or via MGUS, into MM. Interestingly, plasma cells can be found in close contact with Gaucher cells, suggestive of local interaction (Fig. 4).

Fig. 4

Bone marrow aspirate showing plasma cells surrounding a Gaucher cell in a patient with Gaucher disease type I and multiple myeloma

In our study, we measured IL-6, IL-10, and HGF, three factors important for differentiation and/or proliferation of plasma cells. In addition, IL-6 and IL-10 are also involved in inflammation and in abnormal bone remodeling in MM, aspects that are also present in GD. We found elevated IL-10 levels in most patients, especially those with a monoclonal gammopathy, and predominantly normal levels of IL-6 and HGF. Previous studies have also described increased IL-10 levels [4]. However, findings on IL-6 in GD I have been variable [4, 30–32]. Inconsistent results have also been reported for the pro-inflammatory cytokines TNF-α and IL-1β and the chemokine IL-8 [4, 30–33, 52]. Although not included in this study, increases have been described for the growth factor M-CSF (monocyte/macrophage-colony stimulating factor), the monocyte/macrophage activation marker sCD14 (soluble CD14) [31], sIL-2R (soluble IL-2 receptor), and IL-1RA (IL-1 receptor antagonist) [30]. The most impressive increase, both in our study as well in as in the study by Boot et al. [35], has been found for PARC, a chemokine that is assumed to be involved in B-cell differentiation by recruiting T cells and CD-38 negative mantle zone B lymphocytes to antigen-presenting cells.

In addition to the in vivo studies, it has been described that murine macrophages that were stimulated in vitro by glucocerebroside release the pro-inflammatory lymphocyte-activating factor (LAF = IL-1) in a dose-responsive manner. This effect was not seen on incubation with galactocerebroside, sphingomyelin, and ceramidetrihexoside [53]. Possibly, only minor glycolipid accumulation is sufficient for the development of B-cell derangement. In fact, a glucocerebrosidase deficient mouse (L444P homozygote) showed evidence of B-cell proliferation, as well as elevated serum IgG levels, even though storage cells were not found [54].

The heterogeneity in plasma cytokine levels that have been found could be explained by differences in patient populations and cytokine assays. In addition, it is not known whether plasma levels adequately reflect tissue levels. Nevertheless, clearly both pro- as well as anti-inflammatory cytokine levels are disturbed in GD I. It is unlikely that Gaucher cells directly induce inflammation, since Gaucher cells have a phenotype resembling anti-inflammatory alternatively activated macrophages. More likely, pro-inflammatory cytokines are produced by surrounding macrophages, with Gaucher cells compensating for the inflammatory compounds [55].

Now that it is generally accepted that ERT effectively reduces hepatosplenomegaly, cytopenia and skeletal disease, the focus should be shifted to new challenges, including the prevention and treatment of Gaucher associated co-morbidities. Novel data from our study suggest a beneficial effect of ERT on the occurrence and severity of gammopathies in GD patients. First, none of the patients developed MGUS during ERT. We did see progression of MGUS to amyloidosis and MM in two patients. However, since both patients developed these diseases relatively shortly after start of ERT, one could envision that irreversible changes leading to malignant transformation had already taken place, and could not be corrected by ERT. Second, we found that immunoglobulin levels either decreased or remained stable in both patients with and without a monoclonal gammopathy. The only patient with a strong increase in immunoglobulins (IgM) was a patient not using ERT. A clear influence of ERT on levels of FLC, IL-6, and IL-10 was not found in our study. A previous report also found a decrease in immunoglobulin levels during ERT, although only in patients with a polyclonal gammopathy, and not in patients with a monoclonal gammopathy [6]. Decreases in the levels of IL-10 [4], M-CSF, sCD1431, and PARC [35] have been described. Nevertheless, to draw firm conclusions on a possible positive effect of ERT on gammopathies in GD I, our presumptions should be confirmed in larger studies. This would require an international multicenter effort that should aim to establish whether indeed these long-term complications can be prevented by ERT and whether this would justify the early start of treatment.

In summary, there is a high prevalence in GD I of both polyclonal as well as monoclonal gammopathies, including MM. The risk of these diseases increases with age. Mechanisms causing gammopathies remain to be elucidated, but include the disturbance of cytokine levels involved in inflammation and B-cell function. ERT is likely to have a beneficial effect in preventing the occurrence and the progression of gammopathies.