Morphologic differences in the pattern of liver infiltration between systemic AL and AA amyloidosis

Biopsy and necropsy tissue from 31 unselected patients with systemic amyloidosis, in which there was histologic evidence of liver involvement, were reviewed with reference to the location and pattern of amyloid deposition in the liver. Amyloidosis was classified into AA and AL types on the basis of immunohistochemistry and permanganate reaction of the amyloid deposits. Nineteen were categorized as AA (secondary) and 12 as AL (primary) amyloidosis. Deposition of AA amyloid was limited to the walls of vessels in the portal tract, constituting a "vascular" pattern. In AL amyloidosis, the deposits exhibited a "sinusoidal" pattern in that they were seen along hepatic sinusoids as well as in vessel walls. This difference was statistically significant (P less than .001). The histologic pattern of liver infiltration offers a valuable clue in the classification of systemic amyloidosis and provides information that may be useful in the selection of patients for therapy.     

Hepatic amyloidosis. A histopathologic analysis of primary (AL) and secondary (AA) forms.

The liver is a major site of amyloid deposition. The spectrum of histopathologic changes in the liver was studied in 38 patients with systemic amyloidosis (25 with primary or myeloma-associated amyloidosis [AL] and 13 with secondary, reactive [AA] amyloidosis). Overall architectural distortion, alterations of portal triads, as well as predilection for topographic deposition in the parenchyma and/or blood vessel walls were noted. Significant histopathologic differences in AL or AA amyloid liver involvement included 1) portal fibrosis, seen in 7 of 25 (28%) AL patients and 8 of 13 (62%) AA patients (P = 0.05), 2) parenchymal amyloid deposition in 25 of 25 (100%) AL amyloid and 10 of 13 (77%) AA amyloid patients (P = 0.04), and 3) vascular amyloid deposition found in 17 of 25 (68%) with AL amyloid and 13 of 13 (100%) patients with AA amyloid (P = 0.02). These data vary from the widely held concept that deposition of amyloid is predominantly vascular in the AL form and parenchymal in amyloid AA. Clearly, however, in individual cases significant overlap occurred, and characterization of amyloid types based on morphologic distribution of amyloid deposits may be possible in only a minority of cases. In most cases, differentiation of amyloid AL and amyloid AA forms requires clinical, histochemical, immunochemical, and sometimes more elaborate laboratory amino acid sequence studies for accurate identification.     

Distribution pattern of matrix metalloproteinases 1, 2, 3, and 9, tissue inhibitors of matrix metalloproteinases 1 and 2, and α2-macroglobulin in cases of generalized AA- and AL amyloidosis

Matrix metalloproteinases (MMPs) degrade basement membranes and connective tissue and play an essential role in the homeostasis of the extracellular matrix which is disrupted by the deposition of amyloid. This immunohistochemical study investigated the distribution pattern of matrix metalloproteinases (MMP-1, -2, -3, and -9) and their inhibitors [alpha 2-macroglobulin (alpha 2-M), tissue inhibitors of MMPs (TIMP)-1, and TIMP-2] in human AA- and AL amyloid deposits. Specimens of liver, kidney, and spleen from 22 autopsy cases were investigated. Nine patients had suffered from generalized AA amyloidosis, eight from generalized AL amyloidosis, and five from rheumatoid arthritis or tuberculosis with no histological evidence of amyloid. In all amyloidotic and non-amyloidotic patients, each protease and protease inhibitor was detected in almost every organ investigated. In the amyloidotic cases, there was no indication that a specific protease or protease inhibitor was absent or expressed, but a difference was observed in their spatial distribution patterns. The most noticeable difference was found in immunostaining of amyloid. Only MMP-1, -2, and -3, and alpha 2-M were present in AA amyloid deposits, and only TIMP-1 and TIMP-2 were found in deposits of AL amyloid. This is the first study to show that MMP-1, -2, and -3 are present in AA amyloid deposits. They may be involved in tissue remodeling or in proteolysis of the precursor and fibril proteins.     

The pattern of amyloidosis in Malaysia

Congo red screening of routine biopsies at the University Hospital Kuala Lumpur revealed the following categories of amyloidosis: systemic AL (5.9%); systemic AA (3.2%); isolated atrial (14%); primary localized cutaneous (7.5%); other primary localized deposits (3.2%); localized intratumour (58%); and dystrophic (8.6%). Unlike in the West, AA amyloidosis in this population was usually secondary to leprosy or tuberculosis. Liver involvement in AL amyloidosis was shown to exhibit a sinusoidal pattern and differed from the vascular pattern of AA amyloidosis. Within the category of AA amyloidosis, there were two patterns of renal involvement--glomerular and vascular, with the glomerular pattern carrying a more ominous clinical picture. Notable among the localized amyloidoses were isolated atrial amyloidosis complicating chronic rheumatic heart disease, intratumour amyloidosis within nasopharyngeal carcinomas and dystrophic amyloidosis which occurred in fibrotic tissues.     

Splenic amyloidosis: correlations between chemical types of amyloid protein and morphological features

Sixty-one autopsy cases of splenic amyloidosis were reviewed to assess the relationship between the morphological patterns and chemical types of amyloid protein. On the basis of immunohistochemical reactions of amyloid protein, the cases were classified into 34 cases of AA and 27 of AL amyloidosis. Amyloid deposition in the spleen was divided into three major sites: the red pulp, the white pulp, and blood vessels. Red pulp involvement by amyloid was noted in 52% of the AL cases but in none of the AA cases. White pulp amyloid deposition was found in 70% of the AL and 35% of the AA cases. This difference was statistically significant (P less than 0.001). On the other hand, vascular deposition of amyloid was invariably noted in all cases with AA or AL amyloidosis, affecting the AA cases rather severely. These results strongly suggest that the widely held concept of deposition of amyloid as predominantly vascular in AL amyloidosis and parenchymal in AA amyloidosis requires revision. Our findings indicate that parenchymal, especially the red pulp, involvement is a consistent feature of AL amyloidosis, whereas vascular involvement is a finding common to both types of systemic amyloidosis.     

The pattern of amyloid deposition in the lung

A review of routine histopathological samples and autopsies examined at the Department of Pathology, University of Malaya revealed 15 cases of amyloidosis of the lung. Two were localized depositions limited to the lung while in the remainder, lung involvement was part of the picture of systemic amyloidosis. Both cases of localized amyloidosis presented with symptomatic lung/bronchial masses and a clinical diagnosis of tumour. Histology revealed "amyloidomas" associated with heavy plasma cell and lymphocytic infiltration and the presence of multinucleated giant cells. In both cases, the amyloid deposits were immunopositive for lambda light chains and negative for kappa chains and AA protein. One was a known systemic lupus erythematosus patient with polyclonal hypergammaglobulinaemia. The other patient was found to have plasma cell dyscrasia with monoclonal IgG lambda gammopathy. Both patients did not develop systemic amyloidosis. In contrast, lung involvement in systemic AA amyloidosis was not obvious clinically or macroscopically but was histologically evident in 75% of cases subjected to autopsy. Amyloid was detected mainly in the walls of arterioles and small vessels, and along the alveolar septa. It was less frequently detected in the pleura, along the basement membrane of the bronchial epithelium and around bronchial glands. In one case of systemic AL amyloidosis associated with multiple myeloma, an "amyloidoma" occurred in the subpleural region reminiscent of localized amyloidosis. These cases pose questions on (1) whether localized "tumour-like" amyloidosis is a forme fruste of systemic AL amyloidosis and (2) the differing pattern of tissue deposition of different chemical types of amyloid fibrils, with the suggestion that light chain amyloid has a greater tendency to nodular deposition than AA amyloid.     

Visceral organ involvement and extracellular matrix changes in β2-microglobulin amyloidosis – a comparative study with systemic AA and AL amyloidosis

 Patterns of amyloid distribution and extracellular matrix changes in the heart and gastrointestinal tract were compared among β₂-microglobulin (B2M), AA (secondary), and AL (primary and multiple myeloma-associated) amyloidosis cases. B2M amyloid was found to be mainly distributed in the small arterioles, venules, endocardium and muscularis propria of these organs, the deposits characteristically forming subendothelial nodular lesions in the vessels. A marked increase of chondroitin sulfate (CS) was consistently detected in B2M amyloid. Heparan sulfate (HS) also showed an increase in amyloid deposits, but with less reactivity than CS in the small arterioles or venules. Basement membrane structures stained positively for laminin and collagen type IV were replaced by negative amyloid deposits. In the AL cases, the muscularis propria of the gastrointestinal tract was involved in amyloid deposits, as seen for the B2M type, but the vascular amyloid deposits were localized in the media and adventitia of larger vessels. Immunoreactivity for HS was more intense than that for CS, and no increase in laminin or collagen type IV was observed. In the AA cases, amyloid deposits were distributed in the capillaries, small arterioles, interstitium of the myocardium and mucosa. Immunoreactivity for laminin and collagen type IV was marked, and more intense than that for HS and CS. Although the existence of a direct relationship between increase in extracellular matrix material and amyloidogenesis remains to be proven, the observed variation in extracellular matrix changes in the background of each type of amyloidosis may indicate different binding sites of the amyloid precursor proteins, resulting in the specific histological features and distribution. Received: 23 August 1996 / Accepted: 9 January 1997     

Evaluation of systemic amyloidosis by scintigraphy with 123I-labeled serum amyloid P component

BACKGROUND. In systemic amyloidosis the distribution and progression of disease have been difficult to monitor, because they can be demonstrated only by biopsy. Serum amyloid P component (SAP) is a normal circulating plasma protein that is deposited on amyloid fibrils because of its specific binding affinity for them. We investigated whether labeled SAP could be used to locate amyloid deposits. METHODS. Purified human SAP labeled with iodine-123 was given intravenously to 50 patients with biopsy-proved systemic amyloidosis--25 with the AL (primary) type and 25 with the AA (secondary) type--and to 26 control patients with disease and 10 healthy subjects. Whole-body images and regional views were obtained after 24 hours and read in a blinded fashion. RESULTS. In the patients with amyloidosis the 123I-SAP was localized rapidly and specifically in amyloid deposits. The scintigraphic images obtained were characteristic and appeared to identify the extent of amyloid deposition in all 50 patients. There was no uptake of the 123I-SAP by the control patients and the healthy subjects. In all patients with AA amyloidosis the spleen was affected, whereas the scans showed uptake in the heart, skin, carpal region, and bone marrow only in patients with the AL type. Positive images were seen in six patients in whom biopsies had been negative or unsuccessful; in all six, amyloid was subsequently found on biopsy or at autopsy. Progressive amyloid deposition was observed in 9 of 11 patients studied serially. CONCLUSIONS. Scintigraphy after the injection of 123I-SAP can be used for diagnosing, locating, and monitoring the extent of systemic amyloidosis.     

Immunohistochemical and immunochemical study of amyloid in liver affected by systemic Alambda amyloidosis with antibodies against three different regions of immunoglobulin lambda light chain

The purpose of the present paper was to investigate the heterogeneous nature of amyloid deposits in the liver, by immunohistochemical and immunochemical examination of liver samples from cases of immunoglobulin lambda light chain amyloidosis (Alambda amyloidosis) with antibodies generated against the peptides corresponding to the three different regions of the lambda light chain. Amyloid deposits in the hepatic artery tended to react better with anti-lambda(118-134) than with anti-lambda(159-175). Amyloid deposits in the space of Disse tended to react weakly or partially with anti-lambda(118-134) but well with anti-lambda(159-175). Amyloid deposits in the portal vein reacted relatively well with both antibodies. By western blotting of water-extracted amyloid in which amyloid deposits were not stained with anti-lambda(118-134) immunohistochemically, the three antibodies detected 27 kDa bands consistent with the full-length Ig lambda chain and some smaller bands. These findings indicate that amyloid deposits may not be homogeneous in the liver of AL amyloidosis, and that molecular heterogeneity of amyloid fibril protein or a difference in the mode of deposition results in the histopathological heterogeneity of AL amyloid deposits even within a single patient.     

Diagnosis and classification of amyloidosis by an immuno-histological method

Following the recent classification of amyloidosis by the amyloid proteins involved, we decided to approach its tissue diagnosis and chemical classification by an immunohistological method. Post-mortem tissue specimens from various organs of patients with primary and secondary amyloidosis were examined by the immunoperoxidase technique with specific antibodies against proteins AL and AA which respectively characterize primary and secondary amyloidosis. The major advantage of this technique is that it can be applied to formalin fixed, paraffin embedded tissues. The immunoperoxidase technique proved to be extremely sensitive for the detection of amyloid deposits. Moreover, the deposited proteins could be clearly characterized as AL or AA by the specific anti-sera. We therefore believe that the immunooperoxidase technique is extremely useful for the early tissue diagnosis and chemical classification of amyloidosis.     

A putative role for cathepsin K in degradation of AA and AL amyloidosis

The aims of this study were to investigate the role of cathepsin K in the pathology of amyloidosis by demonstrating its presence in multinucleated giant cells (MGCs) adjacent to amyloid deposits, and determining its ability to degrade amyloid fibril proteins in vitro. The study was performed using autopsy and biopsy specimens from patients with AA or AL amyloidosis. In six (55%) patients with AA amyloidosis and seven (58%) patients with AL amyloidosis, variable numbers of CD68-immunoreactive MGCs were found adjacent to amyloid deposits. In each case strong cytoplasmic immunostaining for cathepsin K was found in MGCs; immunostaining of amyloid deposits was present in five (45%) patients with AA amyloidosis and three (25%) patients with AL amyloidosis. In vitro degradation experiments showed that recombinant cathepsin K completely degraded AA amyloid fibril proteins at pH 5.5 as shown by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and Western blotting. Less effective degradation took place at pH 7.4 and there was no degradation in the presence of a general cysteine protease inhibitor (E64) or in the absence of cathepsin K. This is the first study to show that cathepsin K is expressed in MGCs adjacent to amyloid deposits and to demonstrate its ability to degrade amyloid fibril proteins.     

Amyloid protein of vessels in leptomeninges, cortices, choroid plexuses, and pituitary glands from patients with systemic amyloidosis

The cerebrum, cerebellum, and choroid plexuses from 16 patients with systemic amyloidosis, and the pituitary glands from 14 of these patients, were investigated histologically and immunohistochemically. Cerebrovascular amyloid (CVA) was found in the leptomeninges and cortices of six patients with systemic amyloidosis, including two patients with amyloid A protein (AA) amyloidosis related to serum amyloid A protein, one with AL amyloidosis related to immunoglobulin light chain (AL), two with familial type I amyloidotic polyneuropathy (FAP), and one with senile systemic amyloidosis (SSA). CVA protein from two patients with FAP reacted with anti-human prealbumin antibody similar to that of the visceral organs of these two patients. CVA in SSA reacted with anti-human prealbumin antibody and anti-beta protein antibody. Vascular amyloid was frequently noted in the pituitary glands and choroid plexuses of patients with systemic amyloidosis, and was found to be identical to that in the visceral organs (heart, kidney, and intestine) of these patients. CVA in the leptomeninges and cortices from two patients with AA amyloidosis and one with AL amyloidosis reacted with anti-beta protein monoclonal antibody but not with anti-human AA monoclonal antibody, anti-human A lambda antisera, and anti-human A kappa antisera. We suggest that amyloid proteins of AA and AL amyloidosis do not readily accumulate in the vessels in the leptomeninges and cortices even though the proteins circulate, and that beta protein is not derived from a serum precursor.     

Fibronectin and basement membrane components in renal amyloid deposits in patients with primary and secondary amyloidosis.

Kidney biopsies from one patient with primary (AL) and three with secondary (AA) amyloidosis were used for an ultrastructural study of the collocalization of basement membrane proteins and the extracellular matrix protein fibronectin within amyloid deposits. Antibodies against amyloid P component, laminin, and heparan sulphate proteoglycan core protein all reacted with the basement membranes and the amyloid depositions in AA and AL amyloidosis. Monoclonal and polyclonal antibodies against collagen type IV reacted only with the basement membranes. Anti-fibronectin reaction was found in association with the basement membranes in all four cases, while labelling of amyloid depositions was found only in one of the AA amyloid cases and in the AL amyloid depositions. It is concluded that basement membrane components may be of importance for the formation of amyloid fibrils.     

Cerebrovascular involvement in systemic AA and AL amyloidosis: a clear haematogenic pattern

 Amyloid deposits in cerebral vessels are common in β-amyloid diseases (Alzheimer’s disease, congophilic amyloid angiopathy, Down’s syndrome and hereditary cerebral amyloidosis with haemorrhage of the Dutch type). We report of 20 autopsies on patients who had died with systemic amyloidosis of the AA, Aλ and Aκ types: the brains were examined for the occurrence of amyloid. Vascular amyloid was detected in choroid plexus (in 17 of 20 cases), infundibulum (5 of 8), area postrema (6 of 11), pineal body (3 of 7) and subfornical organ (2 of 3), but not in cortical and leptomeningeal vessels. Immunohistochemical classification of the cerebral amyloid and the systemic amyloid syndrome showed identity proving the same origin of both. The distribution is indicative of a haematogenic pattern of amyloid deposition in systemic amyloidosis and is different from that in Alzheimer’s, prion, ATTR and cystatin C diseases. It corresponds to areas of the brain with a ”leaky” blood–brain barrier. Additionally, all the cases with AA amyloidosis exhibited an Aβ coreactivity in choroid plexus vessels. In one exceptional case, Aβ reactivity of AA amyloid also occurred outside of the brain. Received: 2 November 1998 / Accepted: 25 January 1999     

Classification of amyloid deposits in diagnostic cardiac specimens by immunofluorescence

BackgroundAt least 12 distinct forms of amyloidosis are known to involve the heart or great vessels. Patient treatment regimens require proper subtyping of amyloid deposits in small diagnostic cardiac specimens. A growing lack of confidence in immunohistochemical staining for subtyping amyloid has arisen primarily as a result of studies utilizing immunoperoxidase staining of formalin-fixed paraffin-embedded tissue. Immunofluorescence staining on fresh frozen tissue is generally considered superior to immunoperoxidase staining for subtyping amyloid; however, this technique has not previously been reported in a series of cardiac specimens.MethodsAmyloid deposits were subtyped in 17 cardiac specimens and 23 renal specimens using an immunofluorescence panel.ResultsAmyloid deposits were successfully subtyped as AL, AH, or AA amyloid by immunofluorescence in 82% of cardiac specimens and 87% of renal specimens. In all cases, the amyloid classification was in good agreement with available clinical and laboratory assessments. A cross-study analysis of 163 cases of AL amyloidosis reveals probable systemic misdiagnosis of cardiac AL amyloidosis by the immunoperoxidase technique, but not by the immunofluorescence technique.ConclusionsAmyloid deposits can be reliably subtyped in small diagnostic cardiac specimens using immunofluorescence. The practical aspects of implementing an immunofluorescence approach are compared with those of other approaches for subtyping amyloid in the clinical setting.     

Diagnosis and treatment in systemic amyloidosis

Systemic amyloidosis is characterized by the involvement of multiple organs and the presence of an amyloid precursor protein in serum. This disorder is classified into four major forms: immunoglobulin light chain-derived (AL), reactive AA, dialysis-related (beta2M) and hereditary transthyretin (ATTR) type. Heart, kidney, gastrointestinal tract and peripheral nerves are commonly affected by amyloid deposition in systemic amyloidosis and histopathological demonstration of amyloid deposits on any of affected organs is the first step leading to the diagnosis of this disease. Immunohistochemical analysis of amyloid protein on tissue amyloid deposits is necessary to make classification of the disease and DNA testing is also useful in a hereditary form. Amyloidosis had been considered to be an incurable disease but during the past one decade several therapeutic approaches have been employed for the amyloidosis patients with diverse pathogenetic backgrounds: intravenous large dose of melphalan accompanied by autologous peripheral blood stem cell transplantation for AL amyloidosis and liver transplantation for hereditary ATTR type amyloidosis. As a result some amyloidosis patients have been rescued and are now enjoying their own social lives. It is likely that recent advance on the research of amyloidosis has changed the concept of this disease.     

Diagnosis and immunohistochemical classification of systemic amyloidoses

 Fourty-three cases of systemic amyloidosis were identified in an unselected autopsy series from our institute (6305 autopsies between 1979 and 1993) and classified immunohistochemically by means of a panel of antisera directed against five major amyloid fibril proteins. Amyloid A (AA) amyloidosis was the most common type, being found in 21 cases (48.8%). Transthyretin-derived (ATTR) amyloidosis was present in 11 cases (25.6%), and immunoglobulin light chain-derived (AL) amyloidosis in 10 cases (23.3%). A single case (2.3%) contained deposits of more than one type of systemic amyloid. AA amyoloidosis was associated with chronic inflammatory or infectious diseases (81%), malignant tumours (19%) or both (9.5%). Immunoglobulin light chain-derived amyloidoses were associated with myeloma (50%) or primary (idiopathic; 50%). In AA and AL amyloidosis the kidney was the organ most frequently involved. ATTR amyloid affecting mostly the heart and lungs presented as senile systemic amyloidosis. Systemic amyloidosis was the cause of death in 5 cases (12%) and caused symptoms in 17 cases (39%). Our results suggest that most cases can be classified by using a panel of sensitive and specific antibodies against five major amyloid fibril proteins. This technique may make amyloid type-specific therapy possible for AL amyloid patients who do not have evidence of an underlying plasma cell dyscrasia. Received: 9 December 1997 / Accepted: 2 February 1998     

Amyloidose in Leberbiopsien

Introduction

We reassessed the histopathology and origin of amyloid in liver biopsies.

Materials and Methods

All liver biopsies were retrieved from a series of 588 cases with histologically confirmed amyloidosis submitted between February 2006 and January 2009 to the Amyloid Registry of the Charité University Hospital. Liver biopsies had been fixed in formalin and embedded in paraffin. 3-5 μm thick paraffin sections were stained with hematoxylin and eosin and Congo red. Amyloid was classified immunohistochemically, using antibodies directed against amyloid P-component, AA amyloid, apolipoprotein AI, fibrinogen, lysozyme, λ- and κ-light chain, and transthyretin.

Results

Amyloid was found in 46 liver biopsies (29 men, 17 women; mean age 60 years, range 34-87 years). Immunohistochemical classification succeeded in 42 cases. AL amyloidosis was present in 40 (87%) cases and was further categorized into AL amyloid of λ-light chain origin in 26 (57%) cases, and κ-light chain origin in 14 (30%) cases. ATTR and AA amyloidosis were found in a single patient each (2%). In 4 (9%) cases, amyloid remained unclassified.

Conclusions

Hepatic amyloidosis is most commonly AL amyloid of λ- and κ-light chain origin and is often associated with marked parenchymal atrophy.     

Primary amyloidosis A. Immunohistochemical and biochemical characterization.

Primary "idiopathic" amyloidosis is usually related to immunoglobulin light chain (AL) associated with immunocytic dyscrasias, while secondary "reactive" amyloidosis (AA) is related to serum amyloid A protein (SAA) and typically occurs with chronic inflammation, malignancy, or familial Mediterranean fever. In the present study, amyloid fibril protein extracted from frozen and paraffin-embedded tissue from a patient (CAR) with primary systemic amyloidosis proved to be AA protein by immunohistochemical, immunochemical, and amino terminal sequence. Extracts from both frozen and formalin-fixed paraffin-embedded kidney and spleen yielded similar monomers and dimers of the AA protein. The additional high-molecular-weight bands and a distinct 12,000-dalton fragment in the amyloid protein extracted from the formalin-fixed paraffin-embedded lung suggest that different processing of proteins, ie, by polymerization and/or degradation, may occur in different organs.     

A new model of AA-amyloidosis induced by oral pristane in BALB/c mice.

Fifteen male BALB/c mice were given six intermittent oral doses of O.I. ml pristane (2, 6, 10, 14 tetramethylpentadecane) within a period of 9 weeks. Fifteen mice receiving tap water using the same schedule formed the control group. Amyloidosis was first detected in the spleen of a mouse which had died 33 weeks after the first dose and 24 weeks after the last. All six mice which were subsequently autopsied 34-51 weeks after the first dose also showed amyloidosis involving liver and spleen. The most extensive tissue deposits were seen at 37-38 weeks whereas the older mice showed predominantly chronic renal lesions with papillary necrosis, scars and cystic change. Electron microscopy confirmed the identity of the amyloid fibrils and the presence of globular stellate amyloid ''bodies'' in liver and spleen. The amyloid deposits were shown to be made up of AA (amyloid associated) protein using an indirect immunoperoxidase method and a monoclonal rat anti-murine AA protein antibody. We did not find any plasmacytomas or increased numbers of plasma cells in the bone marrow. None of the control mice developed amyloidosis. This new experimental model promises to provide a means of studying several aspects of secondary amyloidosis which may be relevant to the clinical situation.