C4 Glomerulopathy: A Disease Entity Associated With C4d Deposition.

Complement-mediated glomerulonephritis, which includes C3 glomerulopathy, is characterized by dominant staining of C3 with minimal or no immunoglobulin deposits on immunofluorescence studies. We describe a new entity of complement-mediated glomerulonephritis that is characterized by bright C4d staining but with no or minimal C3 or immunoglobulin deposits on immunofluorescence studies. We label this entity as C4 glomerulopathy. C4 glomerulopathy includes C4 dense deposit disease and C4 glomerulonephritis. C4 dense deposit disease is characterized by bright C4d staining and dense deposits along glomerular basement membranes. C4 glomerulonephritis is characterized by bright C4d staining and many mesangial electron-dense deposits, with or without rare intramembranous electron-dense deposits. We describe clinical features and kidney biopsy results in a short series of 3 patients to highlight these findings. All 3 patients presented with proteinuria, and 2 patients also had hematuria. Kidney function was preserved in 2 patients, whereas 1 patient presented with declining kidney function. Evaluation for autoimmune disease, infection, and paraprotein yielded negative results in all patients. Complement levels were normal, although 1 patient had borderline low C4 levels. Kidney biopsy showed mesangial proliferative or membranoproliferative glomerulonephritis with bright C4d staining and absent or minimal C1q, C3, and immunoglobulin. Laser microdissection and mass spectrometry of glomeruli in all 3 patients showed large to moderate numbers of spectra matching C4. Furthermore, analysis of amino acid sequences showed that they were localized to the C4d portion of C4, consistent with immunofluorescence findings. Further studies are required to determine the underlying cause. In summary, we describe a novel complement-mediated glomerulonephritis that is characterized by bright glomerular C4d staining with minimal or absent staining for C1q, C3, and immunoglobulin.

Proteomic detection of immunoglobulin light chain variable region peptides from amyloidosis patient biopsies.

Immunoglobulin light chain (LC) amyloidosis (AL) is caused by deposition of clonal LCs produced by an underlying plasma cell neoplasm. The clonotypic LC sequences are unique to each patient, and they cannot be reliably detected by either immunoassays or standard proteomic workflows that target the constant regions of LCs. We addressed this issue by developing a novel sequence template-based workflow to detect LC variable (LCV) region peptides directly from AL amyloid deposits. The workflow was implemented in a CAP/CLIA compliant clinical laboratory dedicated to proteomic subtyping of amyloid deposits extracted from either formalin-fixed paraffin-embedded tissues or subcutaneous fat aspirates. We evaluated the performance of the workflow on a validation cohort of 30 AL patients, whose amyloidogenic clone was identified using a novel proteogenomics method, and 30 controls. The recall and negative predictive values of the workflow, when identifying the gene family of the AL clone, were 93 and 98%, respectively. Application of the workflow on a clinical cohort of 500 AL amyloidosis samples highlighted a bias in the LCV gene families used by the AL clones. We also detected similarity between AL clones deposited in multiple organs of systemic AL patients. In summary, AL proteomic data sets are rich in LCV region peptides of potential clinical significance that are recoverable with advanced bioinformatics.

Disappearance of immunoglobulins from persistent renal amyloid deposits following stem cell transplantation for heavy-and light-chain amyloidosis.

BACKGROUND: Immunoglobulin (Ig)-related amyloidosis is the most common type of systemic amyloidosis in the developed countries and involves the kidney in most cases. Clinical remission can be achieved with chemotherapy and/or autologous stem cell transplantation (ASCT). Previous case reports have showed persistence of renal amyloid mass in light-chain amyloidosis (AL) even in the setting of hematologic and renal response. METHODS: We report a novel finding in two cases of heavy- and light-chain amyloidosis (AHL) in which monoclonal Ig but not serum amyloid P (SAP), apolipoprotein E (ApoE) or amyloid bulk in the kidney regressed after successful therapy. RESULTS: In the pre-treatment renal biopsies, the amyloid deposits stained for one heavy and one light chains (IgG + λ in one case and IgA + κ in one case). Laser microdissection followed by mass spectrometry (LMD/MS) in both cases showed abundant spectra for Ig heavy and light chains, SAP and ApoE. Both patients achieved a hematologic response with disappearance of the monoclonal protein from serum and urine and normalization of serum-free light chain ratio, but renal response occurred in only one patient. Repeat kidney biopsies showed persistence of fibrillar amyloid deposits, but regression of Ig from the amyloid deposits based on immunofluorescence. LMD/MS on the repeat biopsy performed in one case also showed disappearance of Ig but not SAP or ApoE. CONCLUSIONS: Our finding suggests that effective chemotherapy and/or ASCT in some patients with AHL not only eliminates the circulating pathogenic monoclonal Ig but also the Ig component of amyloid deposits, which may translate into renal response. This, however, may not lead to regression of amyloid deposits themselves. The latter may require more time or addition of therapeutic agents that target amyloid-associated proteins such as SAP, which are not commercially available.

Apolipoprotein CII Amyloidosis Associated With p.Lys41Thr Mutation.

INTRODUCTION: Apolipoprotein CII amyloidosis (AApoCII) is a rare form of amyloidosis. Here, we report a novel mutation associated with AApoCII amyloidosis in 5 patients and describe their clinical, renal biopsy, and mass spectrometry findings. METHODS: Five patients with renal AApoCII p.Lys41Thr amyloidosis were identified from our amyloid mass spectrometry cohort. Clinical features, kidney biopsy, and mass spectrometry findings were analyzed in this rare type of amyloidosis. RESULTS: The patients were older adults (mean age of 71.6 years at diagnosis), presented with nephrotic-range proteinuria, and often had declining renal function. All renal biopsy specimens showed massive mesangial nodules composed of weakly eosinophilic, periodic acid-Schiff negative, Congo red-positive amyloid deposits. There were no interstitial, vascular, or medullary deposits. In all cases, immunofluorescence studies were negative for Igs and electron microscopy showed amyloid fibrils. Proteomic analysis of Congo red-positive amyloid deposits detected large amounts of apolipoprotein CII (APOC2) protein. We also detected APOC2 p.Lys41Thr mutant protein in amyloid deposits of all patients. DNA sequencing in 1 patient confirmed the presence of the mutation. Both mutant and wild-type forms of APOC2 were detected in amyloid deposits of all patients. Molecular dynamic simulations showed the variant mediating a collapse of the native structure of APOC2, thereby destabilizing the protein. CONCLUSION: We propose that AApoCII p.Lys41Thr amyloidosis is a new form of amyloidosis seen in elderly individuals, histologically exhibiting massive glomerular involvement, leading to nephrotic-range proteinuria and progressive chronic kidney disease.

Renal amyloidosis: origin and clinicopathologic correlations of 474 recent cases.

BACKGROUND AND OBJECTIVES: The kidney is the organ most commonly involved in systemic amyloidosis. This study reports the largest clinicopathologic series of renal amyloidosis. DESIGN, SETTING, PARTICIPANTS, & MEASUREMENTS: This study provides characteristics of 474 renal amyloidosis cases evaluated at the Mayo Clinic Renal Pathology Laboratory from 2007 to 2011, including age, sex, serum creatinine, proteinuria, type of amyloid, and tissue distribution according to type. RESULTS: The type of amyloid was Ig amyloidosis in 407 patients (85.9%), AA amyloidosis in 33 (7.0%), leukocyte chemotactic factor 2 amyloidosis in 13 (2.7%), fibrinogen A α chain amyloidosis in 6 (1.3%), Apo AI, Apo AII, or Apo AIV amyloidosis in 3 (0.6%), combined AA amyloidosis/Ig heavy and light chain amyloidosis in 1 (0.2%), and unclassified in 11 (2.3%). Laser microdissection/mass spectrometry, performed in 147 cases, was needed to determine the origin of amyloid in 74 of the 474 cases (16%), whereas immunofluorescence failed to diagnose 28 of 384 light chain amyloidosis cases (7.3%). Leukocyte chemotactic factor 2 amyloidosis and Apo AI, Apo AII, or Apo AIV amyloidosis were characterized by diffuse interstitial deposition, whereas fibrinogen A α chain amyloidosis showed obliterative glomerular involvement. Compared with other types, Ig amyloidosis was associated with lower serum creatinine, higher degree of proteinuria, and amyloid spicules. CONCLUSIONS: In the authors' experience, the vast majority of renal amyloidosis cases are Ig derived. The newly identified leukocyte chemotactic factor 2 amyloidosis form was the most common of the rarer causes of renal amyloidosis. With the advent of laser microdissection/mass spectrometry for amyloid typing, the origin of renal amyloidosis can be determined in >97% of cases.

Clonally related follicular lymphomas and Langerhans cell neoplasms: expanding the spectrum of transdifferentiation.

The traditional model of hematopoiesis is based on unidirectional maturation of hematopoietic precursors into lineage-committed cells. However, recent studies indicate that mature B lymphocytes may demonstrate significant lineage plasticity. We and others have reported transdifferentiation of follicular lymphomas (FLs) into clonally related histiocytic/dendritic cell neoplasms. Here, we describe 2 patients with FL who developed clonally related Langerhans cell neoplasms. The first was a 52-year-old man diagnosed with FL, grade 1. He received immunochemotherapy and had stable disease for 8 years. He then developed increasing lymphadenopathy, and lymph node biopsy showed Langerhans cell sarcoma with no evidence of FL. The second patient was a 77-year-old woman who presented with lymphadenopathy, an abdominal mass, and pulmonary nodules. Lymph node biopsy showed both Langerhans cell histiocytosis and minimal involvement by FL, grade 1. In each case, a combination of immunoglobulin gene rearrangement and fluorescence in situ hybridization studies provided evidence to support a clonal relationship between the FL and Langerhans cell neoplasm. These cases provide striking examples of neoplastic transdifferentiation and expand the spectrum of lesions clonally identical to otherwise typical FL. Awareness of this phenomenon may aid in diagnosis when histologically dissimilar tumors arise synchronously or metachronously in patients with lymphoma.

Role of a glutamate bridge spanning the dimeric interface of human manganese superoxide dismutase.

The function in the structure, stability, and catalysis of the interfaces between subunits in manganese superoxide dismutase (MnSOD) is currently under scrutiny. Glu162 in homotetrameric human MnSOD spans a dimeric interface and forms a hydrogen bond with His163 of an adjacent subunit which is a direct ligand of the manganese. We have examined the properties of two site-specific mutants of human MnSOD in which Glu162 is replaced with Asp (E162D) and Ala (E162A). The X-ray crystal structures of E162D and E162A MnSOD reveal no significant structural changes compared with the wild type other than the removal of the hydrogen bond interaction with His163 in E162A MnSOD. In the case of E162D MnSOD, an intervening solvent molecule fills the void created by the mutation to conserve the hydrogen bond interaction between His163 and residue 162. These mutants retain their tetrameric structure and their specificity for manganese over iron. Each has catalytic activity in the disproportionation of superoxide that is typically 5-25% of that of the wild-type enzyme and a level of product inhibition greater by approximately 2-fold. Differential scanning calorimetry indicates that the hydrogen bond between Glu162 and His163 contributes to the stability of MnSOD, with the major unfolding transition occurring at 81 degrees C for E162A compared to 90 degrees C for wild-type MnSOD. These results suggest that Glu162 at the tetrameric interface in human MnSOD supports stability and efficient catalysis and has a significant role in regulating product inhibition.