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. 2015 Mar 26;10(3):e0119156. doi: 10.1371/journal.pone.0119156

The Spectrum of Kidney Pathology in B-Cell Chronic Lymphocytic Leukemia / Small Lymphocytic Lymphoma: A 25-Year Multicenter Experience

Anne-Laure Poitou-Verkinder 1, Arnaud Francois 2, Fanny Drieux 2, Stéphane Lepretre 3, Bruno Legallicier 1, Bruno Moulin 4, Michel Godin 1,5, Dominique Guerrot 1,5,*
Editor: Maria Pia Rastaldi6
PMCID: PMC4374947  PMID: 25811382

Abstract

Background

Chronic lymphocytic leukemia and small lymphocytic lymphoma are 2 different presentations of the most common B-cell neoplasm in western countries (CLL/SLL). In this disease, kidney involvement is usually silent, and is rarely reported in the literature. This study provides a clinicopathological analysis of all-cause kidney disease in CLL/SLL patients.

Methods

Fifteen CLL/SLL patients with kidney biopsy were identified retrospectively. Demographic, clinical, pathological and laboratory data were assessed at biopsy, and during follow-up.

Results

At biopsy 11 patients presented impaired renal function, 7 patients nephrotic syndrome, 6 patients dysproteinemia, and 3 patients cryoglobulinemia. Kidney pathology revealed CLL/SLL-specific monoclonal infiltrate in 10 biopsies, glomerulopathy in 9 biopsies (5 membranoproliferative glomerulonephritis, 2 minimal change disease, 1 glomerulonephritis with organized microtubular monoclonal immunoglobulin deposits, 1 AHL amyloidosis). Five patients presented interstitial granulomas attributed to CLL/SLL. After treatment of the hematological disease, improvement of renal function was observed in 7/11 patients, and remission of nephrotic syndrome in 5/7 patients. During follow-up, aggravation of the kidney disease systematically occurred in the absence of favorable response to hematological treatment.

Conclusions

A broad spectrum of kidney diseases is associated with CLL/SLL. In this setting, kidney biopsy can provide important information for diagnosis and therapeutic guidance.

Introduction

Kidney diseases are frequently associated with hematologic malignancies. Depending on the type and stage of the malignancy, the spectrum of kidney pathology can be particularly wide, including immune-mediated glomerulonephritis, interstitial monoclonal infiltration and tubular obstruction.

Chronic Lymphocytic Leukemia (CLL) and Small Lymphocytic Lymphoma (SLL) are two different presentations of the most frequent B-cell neoplasm in adults in Western countries, with an annual incidence of 4–30 cases per 100,000 persons per year [1,2]. Although most patients remain asymptomatic, the clinical features of CLL/SLL are highly variable, including presentation, course and outcome. Unlike renal involvement in monoclonal gammapathies, the description of kidney diseases associated with CLL/SLL is currently limited to case reports and small series of immune-mediated glomerulopathies and interstitial infiltration by monoclonal lymphocytes [39].

In this context, the objective of the present study was to provide a systematic description of kidney pathology and clinical characteristics in a well characterized population of CLL/SLL patients referred for kidney biopsy, in order to better delineate the spectrum and the relative frequency of kidney diseases associated with CLL/SLL.

Subjects and Methods

Patients

This study included all the CLL/SLL patients who underwent a kidney biopsy in Haute-Normandie (1 800 000 inhabitants) between 1989 and 2014. During the study period, 3950 kidney biopsies were performed in the 8 hospitals and clinics of the region. All the biopsies were processed and analyzed in a single central reference pathology department, where the samples were systematically included in a tissue bank (Pathology Department, Rouen University Hospital, Rouen, France). Finally, after screening of the central patient database, 15 patients (20 biopsies) were included on the basis of a CLL/SLL diagnosis ascertained before or at the time of the kidney biopsy. Two of the 15 patients were reported in a previous study specifically focusing on glomerulonephritis in CLL/SLL [8]. Demographic, clinical and laboratory data, including results of the nephrological investigations prompting kidney biopsy, were recorded at time of the biopsy, and from the initial to the latest follow-up.

CLL/SLL was diagnosed according to the WHO classification (ICD-0 9823/3) [1,2]. An indicative extrapolation based on data from the Basse-Normandie CLL/SLL registry estimates that approximately 525 new cases of SLL and 2875 of CLL were diagnosed in Haute-Normandie over the 25-year study period. The diagnosis of CLL requires the presence of at least 5.109 B lymphocytes /l in the peripheral blood, over > 3 months, with evidence of monoclonality (CD5, CD19, CD20, CD23) [1,2]. CLL is distinguishable from SLL by its leukemic appearance. The definition of SLL requires a histological analysis of lymph node biopsy, and the clinical presentation includes lymphadenopathy and/or splenomegaly. In this case, lymph node histology shows small lymphocytes with condensed chromatin and, occasionally, small nucleolus. Large lymphoid cells with more prominent nucleoli and dispersed chromatin are typically present, and are usually clustered in pseudofollicles. The Binet staging system classifies CLL in stages A, B, or C according to the number of lymphoid tissues involved (enlarged lymph nodes in the neck, groin, underarms, hepatomegaly or splenomegaly), and to the presence of anemia and thrombocytopenia. Matutes score is based on the most common marker profile in CLL (CD5+, CD23+, FMC7- and weak surface immunoglobulin (SIg) and CD22), and is used to distinguish between typical (Matutes 4 and 5) and atypical CLL, by assigning scores that range from 5 to 0 [10]. General signs were defined as A: no general sign; or B: weight loss > 10% in 6 months, and/or fever > 38°C without alternative diagnosis and/or nocturnal sweating. Tumoral syndrome was defined as the presence of lymphadenopathy and/or extrarenal organ infiltration (hepatomegaly, splenomegaly). Hematological response to treatment was defined according to the reference guidelines [1]. Dysproteinemias were identified by serum protein immunoelectrophoresis and immunofixation.

Nephrotic syndrome (NS) was defined as proteinuria > 3 g/d with albuminemia < 30 g/l. Complete remission was defined as proteinuria < 0.3 g/d, partial remission as proteinuria < 3 g/d, and relapse as proteinuria > 3g/d after initial remission [11]. Acute renal failure was defined by an increase in plasma creatinine > 26.5 micromol/l and/or >150% baseline value, according to the Acute Kidney Injury Network (AKIN) criteria [12]. Kidney function improvement was defined as a decrease in plasma creatinine > 10%, with persistence > 3 months. Chronic kidney disease was defined as a decrease in MRDR eGFR < 90 ml/min/1.73 m² with persistence > 3 months [13].

Kidney pathology

The 20 biopsies were processed in a standardized manner in Rouen pathology department. Light microscopy analysis was performed after fixation in Dubosq Brazil solution, 2-μm paraffin section, and coloration by Masson trichrome, hematoxylin & eosin, Marinozzi silver, and Congo red stainings. Standardized immunofluorescence was performed retrospectively in 2014. 3-μm cryostat sections were incubated with FITC-conjugated antibodies to human Ig gamma, alpha, mu, kappa, and lambda light chains, C3, C4, C1q, fibrinogen, albumin, CD5, CD20, CD23, CD3, Cyclin D1 and CD10. The biopsies were reanalyzed in a blinded fashion by 2 experienced kidney and hematology pathologists. Ultrastructural electron microscopy was performed in 7 patients.

Ethical requirements

This study was in accordance with the Helsinki declaration, and was approved by the local ethics board for non-invasive health research (Comité d'Ethique pour la Recherche Non Interventionnelle CERNI N°E-2014-11, for the Centre de Protection des Personnes Nord-Ouest-I, Rouen University Hospital, Rouen, France), which waived the need for informed consent in this retrospective analysis.

Results

Clinical presentation at kidney biopsy

The clinical features at biopsy are presented in Table 1. The CLL/SLL had been diagnosed before the nephropathy in 7/15 cases, with a mean interval of 61 months from the hematological to the nephrological diagnosis in this setting (range 19–156 months). General symptoms were present in 7/15 patients, and 11/15 patients presented lymphadenopathy, hepatomegaly, and/or splenomegaly. Extrarenal symptoms were present in 4/15 patients (peripheral neuropathy, arthralgia, skin vasculitis, cholestasis).

Table 1. Clinical characteristics at biopsy.

Case Sex Age at biopsy Interval CLL/SLL Nephropathy (m) CLL/SLL Hematological treatment before biopsy Comorbidity HTN Extracellular fluid expansion Extrarenal symptoms General symptoms A/B Tumoral syndrome
Interstitial nephropathy: isolated specific tumoral interstitial infiltrate +/- CLL/SLL-related granulomatosis
1 M 65 36 p CLL N HTN, smoking, dyslipidemia, spondylarthropathy Y N N A Y
2 M 69 19 CLL Cs HTN, smoking, T2D, stroke, alcoholism Y Y N B Y
3 F 51 36 CLL R-FC HTA Y Y N A Y
4 M 57 96 CLL N Smoking, peripheral artery disease Y N N A Y
5 M 77 62 CLL R-FC HTN, smoking, sleep apnoea syndrome Y N N B Y
5bis 78 R-FC + Chlorambucil Y N N A Y
6 M 67 0 CLL N Smoking Y N N B N
Glomerular lesions associated or not with interstitial nephropathy
7 M 73 156 CLL N HTN, smoking Y Y N A N
8 F 57 42 CLL N Preeclampsia N Y N A N
8bis 60 Cs Y Y N A N
9 M 62 0 SLL N HTN Y Y N B Y
10 F 67 19 p CLL N N Y Y Y A N
10bis 69 N Y Y Y B N
11 F 65 0 SLL N Dyslipidemia Y Y Y A Y
12 F 63 19 CLL Chlorambucil T2D, peripheral artery disease Y Y Y A Y
12bis 71 Chlorambucil Y Y N B N
13 M 76 0 SLL N N Y Y N B Y
14 M 62 0 CLL N Dilated cardiomyopathy N Y Y B Y
15 F 67 0 CLL N N Y Y N B Y
15bis 78 Chlorambucil + Fludarabine Y Y N A Y
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p, CLL/SLL diagnosis post-nephropathy; Cs, corticosteroids; R-FC, rituximab+fludarabine+cyclophosphamide; HTN, hypertension; T2D, type 2 diabetes; Y, yes; N, no.

Laboratory and radiological data

In all patients, the kidney biopsy was performed because of renal failure and/or significant proteinuria. The laboratory and radiological results are presented in Tables 2 and 3. MDRD eGFR < 60 ml/min/1.73m² was found in 11/15 patients, (mean 23 ml/min/1.73m², range 7–38). NS was present in 7/15 patients, while normal proteinuria and urine sediment were found in 2 cases. The hematological work-up revealed dysproteinemia in 6/15 patients (cases 4, 5, 10, 11, 12, 14), with cryoglobulinemia in 3 cases (cases 10, 11, 12). Complement activation was found in 5/15 patients (cases 9, 10, 11, 12, 13). Enlarged kidneys were noticed in one patient (case 6).

Table 2. Laboratory and radiological features.

Case AKI/ CKD P. creatinine (micromol/l) MDRD eGFR (ml/min) Proteinuria (g/d) P. albumin (g/l) Hematuria Leukocyturia Dysproteinemia Fanconi Syndrome Complement Kidney length (R/L, mm)
Interstitial nephropathy: isolated specific tumoral interstitial infiltrate +/- CLL/SLL-related granulomatosis
1 CKD 185 / 34 0.3 / 56 N N N N Normal 101 / 110
2 AKI 743 / 7 1 / 39 Y Y N N Normal 120 / 120
3 CKD 178 / 28 0.9 / 43 N Y N N Normal 120 / 120
4 CKD 194 / 36 0.3 / 49 N N IgG kappa 4.6 g/l / kappa BJ Y Normal 120 / 107
5 CKD 247 / 24 0.8 / 44 N N Lambda BJ N Normal 113 / 113
5bis AKI/CKD 638 / 8 1.4 / 41 N N N Y Normal Normal
6 AKI 616 / 8 1.2 / 36 Y Y N N Normal >120 / >120
Glomerular lesions associated or not with interstitial nephropathy
7 CKD 193 / 38 3.8 / 44 Y N N N Normal 118 / 108
8 N 74 / 72 6.1 / 20 N N N N Normal Normal
8bis N 71 / 76 4.6 / 32 Y N IgG lambda N Normal Normal
9 AKI 178 / 36 6.3 / 21 Y N N N Low C3 Normal
10 N 71 / 75 1.2 / 43 Y Y Type II cryoglobulin N Low C3 and C4 117 / 112
10bis CKD 96 / 53 13 / 19 Y Y Type II cryoglobulin N Low C3 and C4 ND
11 CKD 168 / 28 14 / 25 Y Y Type I cryoglobulin, IgG kappa N Low C3 and C4 103 / 108
12 AKI/CKD 536 / 7 >3 / 30 Y Y Type I cryoglobulin, IgG kappa N Low C4 118 / 123
12bis AKI/CKD 769 / 5 4.5 / 25 Y Y IgG kappa N Normal 95 / 95
13 N 100 / 67 >6 / 24 Y Y N N Low C3 and C4 Normal
14 CKD 470 / 12 7 / 24 N N IgG lambda N ND 116 / 100
15 N 79 / 67 6.1 / 30 Y Y N N Normal Normal
15bis CKD 530 / 7 >13 / 28 Y Y N N Normal Normal
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AKI, acute kidney injury; CKD, chronic kidney disease; P, plasma; BJ, Bence Jones proteinuria; ND, no data available.

Table 3. Laboratory and radiological features.

Case Lymphocyte count (/mm3) Cytopenia (0;1;2) Blood flow cytometry Matutes Bone marrow lymphocyte infiltration Binet stage
Interstitial nephropathy: isolated specific tumoral interstitial infiltrate +/- CLL/SLL-related granulomatosis
1 16000 0 Lambda, CD5+ CD19+ CD23+ CD38- SmIg strong 2 76% A
2 70680 2 (Hb,platelets) Lambda, CD5+ CD19+ ND 62% C
3 1380 0 Kappa, CD5+ CD19+ CD23+ CD38- 5 ND B
4 102000 1 (platelets) CD5+ CD19+ CD23+ FMC7- SmIg weak 5 35% B
5 102300 1 (platelets) Lambda, CD5+ CD19+ CD23+ FMC7- CD38- 5 ND C
5bis 7605 2 (Hb, platelets) 5 ND C
6 80170 1 (Hb) CD5+ CD19+ CD23+ FMC7- CD38- CD79b weak SmIg weak 5 ND A
Glomerular lesions associated or not with interstitial nephropathy
7 27200 0 Kappa, CD5+ CD19+ CD23+ 5 ND A
8 36800 0 Lambda, CD5+ CD19+ SmIg weak ND 75% A
8bis 8100 0 ND ND A
9 3652 1 (Hb) CD5+ CD19+ CD23+ CD38+ SmIg strong / ND /
10 3250 0 Kappa, CD5+ CD19+ ND 74% A
10bis 6960 1 (Hb) Kappa, CD5+ CD19+ ND ND ND
11 7691 1 (Hb) Kappa, CD5+ CD19+ CD23- FMC7+ CD79b+ weak SmIg weak / 82% /
12 7100 0 Kappa, CD5+ CD19+ CD23 weak FMC7+ ND 75% B
12bis 11590 2 (Hb, platelets) ND 85% C
13 10350 1 (Hb: AIHA) ND / 78% /
14 7636 0 Lambda, CD5- CD19- SmIg strong ND 37% A
15 9870 1 (Hb) Lambda, CD5+ CD19+ CD23+ SmIg weak 5 49% C
15bis 1110 1 (platelets) 5 55% C
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AIHA, autoimmune hemolytic anemia; SmIg, surface membrane immunoglobulin; Hb, hemoglobin; ND, no data available.

Pathology

Tables 4 and 5 summarize the conclusions of the kidney biopsy analyses. Monoclonal infiltration was evidenced in 10/15 biopsies. All of these 10 patients presented specific and abundant tumoral infiltration, which was generally associated with non specific reactive lymphocytes. The common morphological feature in these cases was a diffuse nodular infiltration, composed of small mature lymphocytes, with small hyperchromatic nuclei, expanding the interstitium at the expense of the tubular structures, the peritubular capillaries, and less frequently the glomeruli (Fig. 1). Immunohistochemistry revealed monotypic lymphocytes (CD20+, CD5+, Cyclin D1-, CD10-). Six patients presented interstitial infiltration without glomerular lesions. Four had a severe infiltration, associated with GFR < 30 ml/min/1.73m², which represented the indication for kidney biopsy. There was no clear association between the intensity of interstitial infiltration, the CLL stage, and the acute vs chronic presentation of kidney failure. A tumoral syndrome was found in 9/10 of the patients with interstitial infiltration, compared to 2/5 patients without interstitial infiltration. Acute kidney injury was attributed to tubular necrosis in 2 patients (cases 6 and 9), and to interstitial infiltration in cases 2, 5, and 12. In the patients with AKI occurring in a context of MPGN, no extracapillary proliferation was found.

Table 4. Kidney biopsy pathology.

Case Light microscopy Glomerular immunofluorescence Infiltrate immunohistochemistry Electron microscopy Definite diagnosis
Interstitial nephropathy: isolated specific tumoral interstitial infiltrate +/- CLL/SLL-related granulomatosis
1 Mild monomorphic diffuse infiltrate Ig alpha Ig mu traces CD20+ CD5+ CD23- Cyclin D1- CD10- CLL infiltrate
2 Moderate monomorphic diffuse infiltrate Normal CD20+ CD5+ CD23- CD10- Cyclin D1- CLL infiltrate
3 Moderate monomorphic focal infiltrate Ig gamma Ig mu C3 C1q traces CD20+ CD5+ CD23- CD10- Cyclin D1- CLL infiltrate
4 Two monomorphic nodules Normal CD20+ CD5+ CD23- CD79a weak CD10- (nodules) CLL infiltrate Granulomatous reaction
Abundant interstitial granulomas
Mild polymorphic diffuse infiltrate
5 One interstitial granuloma ND CD20+ CD5+ CD23- CD10- Cyclin D1- CLL infiltrate Granulomatous reaction
Severe monomorphic diffuse infiltrate
5bis Abundant interstitial granulomas Normal CD20+ CD5+ CD23- CD10- CLL infiltrate Granulomatous reaction
Severe monomorphic diffuse infiltrate
6 Abundant epithelioid non-necrotic peritubular granulomas Normal CD20+ CD5+ CD79a+ CD23- CD10- Cyclin D1- CD1- CLL infiltrate Granulomatous reaction
Severe monomorphic diffuse infiltrate
Glomerular lesions associated or not to interstitial nephropathy
7 MCD Ig mu C3 C4 C1q traces CD20- CD3+ CD5+ CD19- CD23- Cyclin D1- MCD
Mild polymorphic diffuse infiltrate
8 MCD ND / Foot process fusion MCD
8bis MCD Normal / MCD
9 MPGN with capillary thrombi Ig gamma Ig mu kappa lambda C4 C1q, C3 traces CD20+ CD5- CD23- Cyclin D1- (nodule) Abundant subendothelial non-organized non-fibrillar deposits MPGN
One monomorphic nodule, mild polymorphic infiltrate
10 MPGN with endocapillary proliferation ND / Rare non-oriented cylindric 280-nm long 35-nm diameter deposits Cryoglobulin-related MPGN
10bis MPGN with endocapillary proliferation and fibrinoid deposits Ig gamma Ig alpha Ig mu C1q C3 C4 / Cryoglobulin-related MPGN
Pseudo-thrombi
11 MPGN with endo- and extra-capillary proliferation Ig gamma1 kappa C3, C1q traces CD20+ CD5+ CD23+ CD10- Subendothelial granular and fibrillar deposits Cryoglobulin-related MPGN CLL infiltrate
Pseudo-thrombi No fibrillary organization in lymphocytes
Severe monomorphic diffuse infiltrate
12 MPGN Pseudo-thrombi Ig gamma kappa C3 CD20+ CD5+ CD23- CD10- Cyclin D1- Cryoglobulin-related MPGN CLL infiltrate
Moderate monomorphic diffuse infiltrate
12bis MPGN Pseudo-thrombi Ig gamma kappa C3 CD20+ CD5+ CD23- CD10- Cyclin D1- Cryoglobulin-related MPGN CLL infiltrate
Severe monomorphic diffuse infiltrate
13 MPGN appearance Ig gamma kappa C3 ND Endomembranous non-amyloid microfibrillar 8-nm diameter deposits Fibrillary glomerulonephritis CLL infiltrate
Moderate monomorphic focal infiltrate
14 Amyloidosis Ig gamma lambda CD20+ CD5- CD23- CD10- Cyclin D1- Non-oriented multifocal 10-nm-large fibers AHL Amyloidosis Granulomatous reaction
Mild polymorphic infiltrate
One interstitial granuloma
15 Mesangial sclerosis Ig gamma lambda C3 CD20+ CD5+ CD23- Cyclin D1- Subendothelial organized microtubular deposits ITGN
One interstitial granuloma 30-nm long external diameter CLL infiltrate
Mild monomorphic focal infiltrate Granulomatous reaction
15bis Mesangial sclerosis and proliferation, capillary deposits, podocytosis ND CD20+ CD5+ CD23- CD10- Cyclin D1- ITGN
Moderate polymorphic multifocal infiltrate CLL infiltrate
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MPGN, membranoproliferative glomerulonephritis; AHL, heavy- and light-chain amyloidosis; ITGN, immunotactoid/microtubular glomerulonephritis; ND, no data available

MCD, minimal change disease; MPGN, membranoproliferative glomerulonephritis; ND, no data available.

Table 5. Kidney biopsy pathology.

Case Light microscopy Glomerular immunofluorescence Infiltrate immunohistochemistry Electron microscopy Definite diagnosis
11 MPGN with endo- and extra-capillary proliferation; Pseudo-thrombi; Severe monomorphic diffuse infiltrate Ig gamma1 kappa C3, C1q traces CD20+ CD5+ CD23+ CD10- Subendothelial granular and fibrillar deposits; No fibrillary organization in lymphocytes Cryoglobulin-related MPGN CLL infiltrate
12 MPGN; Pseudo-thrombi; Moderate monomorphic diffuse infiltrate Ig gamma kappa C3 CD20+ CD5+ CD23- CD10- Cyclin D1- Cryoglobulin-related MPGN CLL infiltrate
12bis MPGN; Pseudo-thrombi; Severe monomorphic diffuse infiltrate Ig gamma kappa C3 CD20+ CD5+ CD23- CD10- Cyclin D1- Cryoglobulin-related MPGN CLL infiltrate
13 MPGN appearance; Moderate monomorphic focal infiltrate Ig gamma kappa C3 ND Endomembranous non-amyloid microfibrillar 8-nm diameter deposits Fibrillary glomerulonephritis CLL infiltrate
14 Amyloidosis; Mild polymorphic infiltrate; One interstitial granuloma Ig gamma lambda CD20+ CD5- CD23- CD10- Cyclin D1- Non-oriented multifocal 10-nm-large fibers AHL Amyloidosis Granulomatous reaction
15 Mesangial sclerosis; One interstitial granuloma; Mild monomorphic focal infiltrate Ig gamma lambda C3 CD20+ CD5+ CD23- Cyclin D1- Subendothelial organized microtubular deposits; 30-nm long external diameter ITGN; CLL infiltrate Granulomatous reaction
15bis Mesangial sclerosis and proliferation; Capillary deposits; Podocytosis; Moderate polymorphic multifocal infiltrate ND CD20+ CD5+ CD23- CD10- Cyclin D1- ITGN; CLL infiltrate
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MPGN, membranoproliferative glomerulonephritis; AHL, heavy- and light-chain amyloidosis; ITGN, immunotactoid/microtubular glomerulonephritis; ND, no data available.

Fig 1. CLL/SLL infiltrate (case 12).

Fig 1

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(a) Masson trichrome staining. (b) Specific immunostaining to human CD3. (c) Specific immunostaining to human CD5. (d) Specific immunostaining to human CD20. Light microscopy, original magnification, X 40.

Interstitial granulomas were found in 5/15 patients. Light microscopy revealed florid interstitial gigantocellular granulomas, surrounded by lymphocytes (Fig. 2). No tubular basement membrane rupture, cellular necrosis or microcristalline precipitation was observed, and Periodic Acid Schiff, Ziehl and Grocott stainings revealed no microorganism. Immunofluorescence showed no specific interstitial deposit. Granulomas were a prominent feature in cases 4, 6 and on the 2nd biopsy of case 8. The granulomas were associated with monotypic interstitial infiltration (cases 4, 5, 6), or with glomerular deposits (cases 14, 15). No extrarenal granuloma was found in these patients.

Fig 2. Representative cases of interstitial granulomas.

Fig 2

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(a) Case 4. Masson trichrome. Interstitial epithelioid and gigantocellular non-necrotizing granuloma, surrounded by lymphocytes. Original magnification, X 20. (b) Case 6. Hematoxylin and eosin staining. Granuloma associated with severe diffuse CLL/SLL monomorphic infiltrate. Original magnification, X 40.

Nine patients presented glomerular lesions, of which 4/9 were associated with monoclonal interstitial infiltration. Membranoproliferative glomerulonephritis (MPGN) was present in 5 patients (cases 9–13). Light microscopy revealed typical mesangial and/or endocapillary proliferation, double contours of the basement membrane, and endomembranous deposits (Fig. 3). The deposits were related to a circulating cryoglobulin in cases 10–12. In these 3 patients an important polymorphic infiltration with polymorphonuclear cells, lymphocytes and macrophages associated with endomembranous deposits was responsible for the formation of pseudothrombi in capillary loops, and fibrinoid deposits in one patient (case 10). The ultrastructural study revealed proliferative mesangial cells, podocyte foot process fusion, and endomembranous homogeneous granular deposits. The immunofluorescence confirmed the presence of the circulating cryoglobulin within glomerular deposits. Hepatitis B, C, and HIV serologies were negative in all patients. In patients 9 and 13 neither cryoglobulin nor dysproteinemia were detected. Case 13 presented monotypic gamma and kappa deposits together with positive C3 on immunofluorescence analysis, and decreased C3 and C4 in the peripheral blood tests. Large endomembranous deposits characterized by 8-nm diameter microfibrillar structures, organized in 0.96-μm long and 0.45-μm large bundles composed of approximately 12 elements were evidenced, leading to the diagnosis of fibrillary glomerulonephritis.

Fig 3. Representative cases of MPGN.

Fig 3

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(a) Case 10. Light microscopy, Masson trichrome staining. Cryoglobulin-related MPGN. Endocapillary proliferation, fibrinoid necrosis and pseudo-thrombi. Original magnification, X 20. (b) Case 11. Light microscopy, Masson trichrome. Endo- and extracapillary proliferation. Note the severe CLL/SLL monomorphic infiltrate. Original magnification, X 40. (c) Case 11 (IgG kappa type I cryoglobulin). Immunofluorescence microscopy. Endomembranous deposits of IgG1, kappa, C3, C1q. Original magnification, X 20. (d) Case 11. Electron microscopy. Subendothelial granular and fibrillar deposits. Bar = 1200 nm.

Patient 15 presented an immunotactoid glomerulonephritis with organized microtubular monoclonal immunoglobulin deposits. Light microscopy revealed mesangial sclerosis with focal mesangial proliferation (Fig. 4). Large globular deposits were observed in the capillary loops. Monotypic IgG lambda was found within the deposits, with endocapillary C3. The ultrastructural analysis revealed subendothelial organized microtubular deposits, characterized by a 30-nm long external diameter.

Fig 4. GOMMID (case 15) (a) Light microscopy.

Fig 4

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Masson trichrome. Mesangial sclerosis with focal mesangial proliferation. Note mild monomorphic focal CLL/SLL infiltrate. Original magnification, X 10. (b) Light microscopy. Masson trichrome. Mesangial sclerosis and proliferation, capillary deposits. Original magnification, X 40. (c) Immunofluorescence microscopy. Monotypic Ig lambda deposits. The same fluorescence patern was obtained with an anti-C3 antibody (data not shown). (d) Electron microscopy. Subendothelial organized microtubular deposits, 30-nm external diameter. Bar = 1200 nm.

Two patients presented minimal change lesions, with normal light microscopy, normal immunofluorescence, and foot process effacement on the ultrastructural analysis (cases 7, 8).

Patient 14 had glomerular heavy- and light-chain amyloidosis (AHL) related to a circulating IgG lambda monoclonal protein. Light microscopy found very large Congo red positive dichroic deposits in the mesangium, the subendothelial space of glomerular capillaries, Bowman’s capsule, the interstitium, the tubular basement membrane and the arterioles (Fig. 5). Immunofluorescence revealed an equally intense staining for gamma and lambda chains, and ultrastructural analysis showed that the deposits were composed by non-oriented 10-nm large fibers.

Fig 5. AHL amyloidosis (case 14) (a) Light microscopy.

Fig 5

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Masson trichrome staining. Massive amorphous deposits in the mesangium and extending to the subendothelial space of glomerular capillaries, Bowman’s capsule, the interstitium, the tubular basement membrane and the arterioles. Original magnification, X 20. (b) Apple green birefringence detected under polarized light. Original magnification, X 20. (c) Immunofluorescence microscopy. Monotypic Ig lambda deposits. Equally intense staining for heavy and light chains. (d) Electron microscopy. Non oriented, randomly arranged, 10-nm diameter fibrils. Bar = 1250 nm.

Evolution

The mean post-biopsy follow-up was 86 months (range 3–199 months) (Tables 6 and 7). All but 1 patient (case 7) received corticosteroids and/or cytotoxic treatment. Two patients with severe interstitial infiltration received methylprednisolone pulses followed by cytotoxic chemotherapy, with favorable renal outcomes (cases 2, 6).

Table 6. Post-biopsy follow-up and clinical course.

Case Treatment Pcreat / MDRD eGFR before/post treatment Proteinuria (g/d) NS Histology Dialysis CLL/SLL Follow-up Cause of death
before/post treatment Alive / Deceased
Interstitial nephropathy: isolated specific tumoral interstitial infiltrate +/- CLL/SLL-related granulomatosis
1 Cs 185/81 0.3 / < 0.3 / N N Stability 8.3 y Deceased Acute alcoholic hepatitis
Sepsis
2 CHOP Cs 743/173 1 / 0.9 / N N Stability 3 m Deceased ND
3 R-FC 178/147 0.9 / 0.7 / N N CR 5 y Alive /
4 Chlorambucil 194/180 0.3 / 0.3 / N N PR 18 m Alive /
5 Chlorambucil 247/609 0.8 / 1.3 / CLL infiltrate Granulomatous reaction N Stability 4 y Alive /
5bis N / / / N Y Progression
6 R-Bendamustine Cs 616/296 1.2 / < 0.3 / N Transient hemodialysis (1 m) CR 3 m Alive /
Glomerular lesions associated or not to interstitial nephropathy
7 N / / Persistent NS N Y Stability 11 y Deceased Cardiovascular disease Sepsis
8 Cs 74/91 6.1 / 0.13 CR and relapse MCD N PR 16.5 y Alive /
8bis Chlorambucil Cs 71/79 4.6 / <0.3 CR N N CR
9 R-Bendamustine 178/85 6.3 / 1.4 PR N N PR 6 m Alive /
10 N / / / Cryoglobulin-related MPGN N Progression 9 y Alive /
10bis Cyclophosphamide Cs 96/44 13 / <0.3 CR N N CR
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Cs: corticosteroids; CHOP: cyclophosphamide+ adriamycin+ vincristine+ prednisone; R-FC: rituximab+ fludarabine+ cyclophosphamide; R-Bendamustine: rituximab+ bendamustine; Pcreat: Plasma creatinine (micromol/l); NS: nephrotic syndrome; CR: complete remission; PR: partial remission; ESRD: End Stage Renal Disease; MCD: minimal change disease; Y, yes; N, no; ND, no data available.

Table 7. Post-biopsy follow-up and clinical course.

Case Treatment Pcreat / MDRD eGFR before/post treatment Proteinuria (g/d) NS Histology Dialysis CLL/SLL Follow-up Cause of death
before/post treatment Alive / Deceased
11 Chlorambucil Chlorambucil; Rituximab 168/66; 83/74 14 / 0.19; 5.1/ <0.3 CR and relapse*; CR N N Remission and relapse*; CR 9 y Alive /
12 Chlorambucil 536/180 > 3 / 0.15 CR and relapse* Cryoglobulin-related MPGN N Remission and relapse* 8 y Deceased Febrile medullary aplasia Acutisation CLL/ ESRD
CLL infiltrate
12bis Chlorambucil Cs 769/790 Dialysis 4.5 / Dialysis Persistent N Y Progression
CHOP
13 Chlorambucil 100/70 > 6 / <0.3 CR N N CR 9 y Deceased ND
14 Alkeran Cs 470/700 Dialysis 7 / Dialysis Persistent N Y Stability 9 y Deceased ND
15 Chlorambucil; Chlorambucil; Fludarabine; Chlorambucil 79/85 6.1 / < 0.3 CR and relapse; CR and relapse*; CR and relapse*; Persistent NS ITGN CLL infiltrate N Remission; Relapse*; Relapse*; Progression 16 y Alive /
15bis Rituximab 530/300 Dialysis > 13 / Dialysis PR N Y Stability
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Cs: corticosteroids; CHOP: cyclophosphamide+ adriamycin+ vincristine+ prednisone; R-FC: rituximab+ fludarabine+ cyclophosphamide; R-Bendamustine: rituximab+ bendamustine; Pcreat: Plasma creatinine (micromol/l); NS: nephrotic syndrome; CR: complete remission; PR: partial remission; ESRD: End Stage Renal Disease; MCD: minimal change disease; ITGN, immunotactoid/microtubular glomerulonephritis; Y; yes; N, no; ND, no data available.

*: Simultaneous relapses in NS and CLL/SLL

Among the 7 patients presenting with NS and treated with cytotoxic agents, transient or persistent complete remission was observed in 5 patients. Partial remission was observed in patient 9 (MPGN), while patient 14 (AHL amyloidosis) had a persistent NS. In 4 patients with NS relapse observed during the follow-up, progression of the hematological malignancy was also present. In 7/11 patients presenting with decreased eGFR at biopsy the eGFR increased after treatment. Four patients had a negative decline of eGFR after treatment, which occurred in the absence of hematological response (cases 5, 12bis, 14, 15bis). Five patients had a second kidney biopsy for relapse of NS or rapid decrease in eGFR. In all cases, the second kidney biopsy revealed progression of the renal lesions initially identified, with superimposed or increased interstitial infiltration in cases 5, 12, and 15.

At the last follow-up, progression of the kidney disease had required extrarenal suppleance therapy in 5 patients. Patient 6 needed transient hemodialysis, which was withdrawn after post-treatment recovery of kidney function. The mean plasma creatinine at the end of the follow-up, excluding the 5 patients requiring dialysis, was 122 micromol/l.

Discussion

This study attempted to better describe the spectrum of kidney pathology associated with CLL/SLL. The first occurrence of kidney disease in CLL was described in 1957 by Scott et al, in a patient presenting with NS [14]. Subsequently, case reports and small series have underlined the diversity of lesions which may be found in CLL/SLL, including interstitial infiltration, immune-mediated glomerulonephritis, and drug toxicity. With the inclusion of 15 patients, the present study provides the largest series of all-cause kidney disease in CLL/SLL currently reported (Table 8). CLL is usually diagnosed in patients > 55 y (90%), with a sex ratio of 1.5 [15]. In this study the patients had a mean age 65.2 at the first kidney biopsy, younger than in the CLL/SLL general population (mean age 72), suggesting that complications due to kidney involvement can be diagnostic in CLL/SLL. Alternatively, patients with kidney disease could also present with more aggressive forms of CLL/SLL.

Table 8. Previously reported series.

Reference Patients Tumoral MPGN MCD Amyloidosis Other proliferative GN Interstitial granuloma MN Fibrillary GN ITGN MIDD FSGS
n infiltrate
Present study 15 10 5 2 1 5 1 1
Moulin et al. 1992 3 13 6 8 1 1 2 1 1
Kowalewska et al. 2011 32 7 7 2 2 1 1 1
Seney et al. 1986 4 2
Dabbs et al. 1986 33 12 1 2 5
Da'as et al. 2001 10 3 1 1
Hill et al. 2002 3 2 1
Barbour et al. 2011 2 1 2
Cameron et al. 1974 2 1 1
Audart et al. 2008 2 1 1
Sethi et al. 2010 2 2
Sanchorawala et al. 2006 37 2 2
Nasr et al. 2012 3 3
Kourelis et al. 2013 39 4 4
TOTAL 74 25 21 8 8 8 5 4 4 4 3 2
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MCD, minimal change disease; FSGS, focal segmental glomerulosclerosis; MN, membranous nephropathy; MPGN, membranoproliferative glomerulonephritis; GN, glomerulonephritis;

MIDD, monoclonal immunoglobulin deposition disease; DN, diabetic nephropathy; ITGN, immunotactoid/microtubular glomerulonephritis.

Single case reports published and not included in these case series are not presented in the Table

Renal interstitial infiltration is a frequent finding in autopsy series of CLL patients, estimated between 44 and 90% of patients. The B-cell infiltrate can either be nodular or diffuse, and its localization classically begins in the subcapsular cortex, at the corticomedullar junction, and along the vasa recta [16,17]. In our patients presenting with isolated infiltrates the lymphocytes were monotypic and presented a monomorphic, regular, and mature aspect, separating and directly infiltrating the tubular epithelium, surrounded by local accumulation of extracellular matrix. Usually, the infiltration of the kidneys by monoclonal B cells is bilateral, asymptomatic, and is diagnosed or suspected in late stages of the disease [18]. Even a massive infiltration of both kidneys can remain totally asymptomatic [5]. Urine sediment is usually normal, and proteinuria < 1 g/d. On the other hand, kidney infiltration can present as acute kidney failure or moderate chronic kidney disease [6,7,19,20]. In our study, although 10 patients presented a CLL/SLL-related infiltrate on kidney biopsy, only one patient had a typical enlargement of kidneys. The intensity of interstitial infiltration is usually correlated with the severity of kidney failure, as suggested by the cases of several patients in our study (cases 2, 3, 5, 6) [16,21]. The mechanisms whereby the infiltrate may contribute to decrease GFR are not univocal, and in particular not limited to a mechanical compression [22]. Proinflammatory and profibrotic cytokines released by the infiltrating and/or resident cells could play an important role in tubulo-interstitial injury [23,24]. Accordingly, observational studies have shown that interstitial fibrosis was more frequent in areas of interstitial infiltration [16,21]. We found no clear association between the stage of CLL/SLL and the severity of renal failure, similar to a previous study [25]. The presence of extrarenal tumoral syndrome was generally associated with interstitial infiltration on the kidney biopsy. An important differential diagnosis for CLL/SLL-related interstitial infiltration is acute interstitial nephritis. The predominance of T cells, and/or the mixed lymphocyte population within interstitial aggregates which respect the normal parenchymal architecture are strong arguments against the diagnosis of CLL/SLL-related infiltration [21].

Interstitial granulomatous nephritis is found in less than 1% of native kidney biopsies, and 6–9% of biopsies revealing interstitial nephritis [26,27]. The most frequent causes of granulomas are infections, drug reactions, and inflammatory disorders, which were systematically excluded in the patients of the present study. In CLL/SLL, the presence of granulomas on kidney biopsy has been reported twice previously [4,28]. Granulomas are a relatively frequent finding in patients with Hodgkin’s lymphoma (14%), and non-Hodgkin’s lymphoma (7%), and are thought to be due to sarcoid reactions against tumor-derived antigens [29]. In this context, the activation of macrophages is typically mediated by T cells, which may explain the lower prevalence in B-cell malignancies. A series of 5 CLL/SLL patients with lymph node and bone marrow granulomas has been reported, which were related to mycobacteria or sarcoidosis, underlining the importance of excluding opportunistic infections in this context [30].

The association of glomerular disease in CLL/SLL has been reported in approximately 50 patients, mainly in case reports and in small cases series [31]. The most frequently reported lesions are MPGN (36%) and membranous nephropathy (19%), the latter frequently presenting with atypical characteristics such as proliferative lesions and monotypic deposits [31]. Less frequently, MCD, focal segmental glomerulosclerosis, amyloidosis, and immunotactoid/microtubular glomerulopathies may be found. A difficult issue in this context is to determine whether or not the glomerular injury is related to the hematologic malignancy. Classical criteria for paraneoplastic glomerulopathies include a chronological relation (GN often revealing the malignancy, or simultaneously diagnosed), a suspected pathophysiological link (such as dysproteinemia with or without cryoglobulinemia, cytokine-altered glomerular permeability, or T-cell dysregulation), and a parallel evolution of the malignancy and the glomerulopathy with specific cytotoxic treatment [32,33]. In our study, 6/15 patients presented a monoclonal dysproteinemia, which is higher than reported in the general population of CLL patients [34,35]. The monoclonal protein secreted by the B-cell clone can either be directly involved in the pathogenesis of the lesions, as is the case in fibrillary glomerulopathy, immunotactoid/microtubular glomerulonephritis, AL amyloidosis, and type I/II cryoglobulinemia, or indirectly, as in cases of MPGN not related to cryoglobulinemia.

MPGN is one of the most frequent kidney diseases described in association with CLL/SLL (Table 8). In our study, 5 patients presented a MPGN, including 2/5 without any detected dysproteinemia. Glomerular lesions associated with cryoglobulinemia are either due to immune complexes or to the direct targeting of native or planted glomerular antigens by the monoclonal cryoglobulin [8,36]. Irrespective of the mechanism leading to cryoglobulin deposition, glomerular infiltration by macrophages is frequent in this context and is believed to play an important pathogenic role [37]. Patient 13 presented a monotypic IgGκ fibrillary GN. The presentation of this patient was unusual since deposits in fibrillary GN are described as polytypic in 90% cases, and hypocomplementemia is rare [38,39]. In addition, fibrillary GN is exceptionally reported in CLL/SLL. Interestingly, Schneider et al reported a very similar case, suggesting an important role for complement activation in the pathogenesis of the glomerular lesions in this context [40]. As opposed to the glomerular lesions found in cryoglobulin-related MPGN, immunotactoid/microtubular glomerulonephritis is usually not associated with macrophage infiltration, thrombi or vasculitis-like lesions [38]. The microtubular deposits are monotypic, as in patient 15, their intensity being related to the quantity of the monoclonal component secreted by the B-cell clone [41]. The microtubular organization present in glomerular deposits can also be found in the Golgi apparatus of the malignant lymphocytes [41].

The literature describes 12 previous cases of CLL/SLL-related MCD [4245]. The pathophysiology of this association is unclear. Both a disturbed pattern of cytokine production by the B clone and a T-cell dysfunction have been proposed. The parallelism between the evolution of the hematological disease and the podocytopathy before and after treatment strongly suggests an immune-mediated link involving the malignant clone.

Immunoglobulin-derived amyloidosis accounts for approximately 85% of amyloidosis diagnosed on kidney biopsy [46]. Few cases of CLL/SLL-related amyloidosis have been reported to date, despite the fact that up to 35% of CLL/SLL patients present abnormal serum free light chain ratios [4751]. The reason for this theoretical discrepancy may be that the amount of circulating free light chains is usually moderate in CLL/SLL, and that CLL/SLL clones more frequently produce kappa than lambda light chains, lambda light chains typically being more amyloidogenic than kappa [50,51]. In our study one patient presented IgG lambda AHL amyloidosis, which is a particularly rare finding, AHL amyloidosis accounting for less than 5% of Ig-derived renal amyloidosis [46].

This study provides an overview of kidney diseases associated with CLL/SLL requiring biopsy due to decreased eGFR and/or NS. Undoubtedly, the clinical context leading to the indication of histological examination yields a bias in the results of this study. The comparison of our results with those of autopsy series strongly suggests that the prevalence of isolated CLL/SLL-related interstitial infiltration is underestimated in the present study. Inversely, the prevalence of immune-mediated glomerulonephritis is most probably overestimated, compared to the general population of CLL/SLL patients. Yet, we believe that this study provides a valuable overview of the renal lesions expected in CLL/SLL patients with a potential indication for kidney biopsy. Due to the broad spectrum of glomerular and interstitial diseases associated with CLL/SLL, and to the limits of clinicopathological correlations, kidney biopsy remains an essential tool in selected patients with decreased eGFR and/or NS. An important result of this study is that the conclusions of the kidney biopsy led to corticosteroid and/or cytotoxic treatment, and to subsequent favorable renal and hematological responses in a large number of patients.

Acknowledgments

We thank Prof. Fabrice Jardin, Prof. Hervé Tilly, Dr. Aspasia Stamatoullas (hematology department, Centre Henri Becquerel, Rouen), Dr. Bernard Lenormand (hematology department, Rouen university hospital, Rouen), Dr. Assem Alrifai (hematology department, Evreux hospital, Evreux), Dr. Jean-Michel Picquenot (pathology department, Centre Henri Becquerel, Rouen), and Dr. Catherine Bessin, Dr. Olivier Drouineau, Dr. Stéphane Edet (nephrology department, Dieppe hospital, Dieppe), Dr. Pascal Seris (nephrology department, Croix-Rouge hospital, Bois Guillaume), Dr. Caroline Fréguin (nephrology department, Elbeuf-sur-Seine), and Dr. Frank Le Roy, Dr. Isabelle Etienne, Dr. Mélanie Hanoy, Dr. Dominique Bertrand (nephrology department, Rouen University Hospital, Rouen), for kindly providing access to the patients’ data.

Data Availability

All relevant data are within the paper.

Funding Statement

The authors have no support or funding to report.

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