Alzheimer's disease brain-derived ubiquitin has amyloid-enhancing factor activity: behavior of ubiquitin during accelerated amyloidogenesis

Animal model for the pathogenesis of reactive amyloidosis

The pathogenesis of amyloidosis is not well understood. Here, Zafer Ali-Khan, Weihua Li and Sic L. Chan present a metazoan parasite mouse model of reactive amyloidosis, review the relationship between chronic inflammation and multiorgan AA amyloidosis and postulate how ubiquitin might function in the processing of serum amyloid A and in AA amyloid formation in the endosomes-lysosomes of activated murine reticuloendothetial cells.

[BIG-H3 protein: mutation of codon 124 and corneal amyloidosis]

In 1997, a group of hereditary corneal dystrophies was related to mutations in the TGFBI (BIGH3) gene. Within this group, some corneal dystrophies present particular biochemical features in that they are characterized by corneal amyloid deposition. Contrary to clinical and genetic knowledge, the biochemical characteristics of the encoded protein (Big-h3) and the mechanisms of its amyloid conversion remain unclear. We review the current knowledge on the Big-h3 protein and focus on the behavior of the codon 124 region. We discuss this protein's mechanisms of amyloid conversion from our results and previous reports as well as from other types of amyloidosis. These data provide a better understanding of the putative processes leading to the phenotypic variations linked with their respective codon 124 mutation.

Ubiquitin and the molecular pathology of neurodegenerative diseases

Ubiquitin plays a central role in normal cellular function as well as in disease. It is possible to group ubiquitin-immunostained structures into several main groups, the most distinctive being the ubiquitin/intermediate filament/alphaB crystallin family of inclusions that seem to represent a general cellular response to abnormal proteins recently termed the aggresomal response. While ubiquitin immunohistochemistry is a very useful technique for detecting pathological changes and inclusion bodies in the nervous system this alone is not enough to classify inclusions, and a panel of antibodies is recommended to clarify any findings made by screening tissues with anti-ubiquitin. Several mechanistic possibilities now exist to explain the accumulation of ubiquitinated proteins in cells of the nervous system, understanding of which should lead to new therapeutic advances in the group of chronic neurodegenerative diseases.

Amyloid enhancing factor and dietary transmission in accelerated amyloid A amyloidosis

The etiology and pathogenesis of amyloid A (AA) amyloidosis that may occur as an occasional complication of chronic inflammatory and infectious diseases are poorly understood. The preamyloid phase of experimentally induced AA amyloidosis can be greatly shortened in recipient animals by intravenous or intraperitoneal transfer of amyloid enhancing factor (AEF) when there is a concomitant inflammatory episode. AEF is an operational term applied to poorly characterized tissue extracts and increased AEF activity that precedes amyloid deposition. We now report that AA is rapidly formed in mice following oral administration of an AEF preparation that does not contain AA peptides. This finding indicates that a transmissible agent present in diet may be a contributory factor in amyloid fibril formation.

An immunohistochemical study of amyloid P component, apolipoprotein E and ubiquitin in human and murine amyloidoses

Amyloid P component (AP) and apolipoprotein E (Apo E), which are known to be minor constituents of amyloid deposits, commonly are associated with almost all types of amyloid deposits. In this study, the distribution of AP-, Apo E- and ubiquitin (Ub)-immunoreactivity (IR) in amyloid deposits in the liver and spleen of human systemic amyloidosis (34 autopsy cases: 17 immunoglobulin light chain derived, 17 amyloid A protein derived) and experimental murine amyloidosis is examined using an immuno-histochemical technique. In human cases, all of the amyloid deposits examined showed colocalization of AP- and Apo E-IR with individual amyloid proteins. In experimental amyloidosis, AP-IR of amyloid deposits in the liver and spleen and Apo E-IR in the liver were seen uniformly throughout this experiment. In contrast, Apo E-IR in the spleen was not uniform at the phase of amyloid deposition. At 4 weeks and at 16 weeks after casein injection, Apo E-IR was unevenly distributed in amyloid deposits in the perifollicular area; however, from 6 to 12 weeks it was seen to be uniform. Ubiquitin-IR of amyloid deposits in human cases was seen in 22 of 34 livers and in 22 of 33 spleens. In experimental amyloidosis, Ub-IR of amyloid deposits was demonstrated in the space of Disse in all mice examined, and there appeared to be a gradual increase in intensity with the amount of amyloid deposition. However, in the spleen, amyloid deposits did not react with anti-Ub antibody in any phase of amyloid induction. These results suggest that Apo E and Ub are not always associated with the process of amyloid deposition and may appear in a deposit after the deposition.

Immunolocalization of serum amyloid A and AA amyloid in lysosomes in murine monocytoid cells: confocal and immunogold electron microscopic studies

Murine AA amyloid (AA) protein represents the amino-terminal two-third portion of SAA2, one of the isoforms of serum amyloid A. Whether plasma membrane-bound or lysosomal enzymes in activated murine monocytoid cells degrade SAA2 to generate amyloidogenic AA-like peptides is not clearly understood, although AA has been localized in the lysosomes. Here we show, using confocal and immunogold microscopy (IEM), that both SAA and AA localize in lysosomes of activated monocytoid cells from amyloidotic mice. Rabbit anti-mouse AA IgG (RAA) and two monoclonal antibodies against murine lysosome-associated membrane proteins (LAMP-1 and LAMP-2) were used to immunolocalize SAA/AA and lysosomes, respectively. Confocal analysis co-localized both anti-RAA and anti-LAMP-1/LAMP-2 reactivities in the perikaryal organelles which by IEM proved to be electron-dense lysosomes. LAMP-1/LAMP-2-specific gold particles were also localized on lysosomal and perikaryal AA. The results suggest sequestration of SAA into the lysosomes. Since monocytoid cells are not known to phagocytose native amyloid fibrils, our results implicate lysosomes in AA formation.

Ubiquitin profile in inflammatory leukocytes and binding of ubiquitin to murine AA amyloid: immunocytochemical and immunogold electron microscopic studies

Lysosomes in activated murine monocytoid cells have been implicated in AA amyloid formation. The pathophysiology of this process is not well understood. Previous studies into the nature of the relationship between ubiquitin (UB), possessing intrinsic amyloid enhancing factor (AEF) activity; serum amyloid A (SAA), the precursor protein of AA amyloid; and activated monocytoid cells have indicated a temporal and spatial relationship between these proteins and tissue AA amyloid deposits. To extend these findings, we have examined murine peritoneal leukocytes and splenic tissues during the early amyloid deposition phase by immunocytochemical and immunogold electron microscopic methods using monospecific anti-ubiquitin and anti-mouse AA amyloid antibodies. We show here enrichment of endosome-lysosome-like (EL) vesicles in the activated monocytoid cells with UB and SAA, and the presence of UB-bound AA amyloid fibrils in the EL vesicles, perikarya, and interstitial spaces. The importance of these findings is emphasized by the fact that activated monocytoid cells, containing UB in the EL vesicles, sequester and eventually localize SAA in their EL vesicles, and that UB binds to the EL-contained AA amyloid fibrils. These findings may also have functional consequences for studies on the role of EL and UB in amyloidogenesis.

Antigenic determinant properties of neurofibrillary tangles. Relevance to progressive supranuclear palsy

Neuronal cytoskeleton is composed of microfilaments, neurofilaments and microtubules which show distinctive ultrastructural characteristics. Different groups of antibodies against neurofilaments and microtubule associated proteins which were grouped according to their specificity for proteins of perykarium, axons and/or dendrites have been produced. A 8.6 kD polypeptide called ubiquitin has been recognized as one of the heat shock proteins. Ubiquitin is implicated in the non-lysosomal degradation of abnormal proteins and other proteolytic intracellular mechanisms. Several immunohistological studies on Alzheimer's disease (AD)-neurofibrillary tangles (NFTs) demonstrated that antibodies for different normal cytoskeletal components bind to NFTs-bearing neurons. AD-NFTs could be also demonstrated using antibodies for the beta-amyloid protein. The production and accumulation of abnormal proteins such as those observed in AD-NFTs induce a ubiquitin-mediated degradative pathway to remove them. It has been demonstrated that ubiquitin is covalently associated with insoluble neurofibrillary material of AD-NFTs. Topographical differences in the distribution of NFTs underscore that different neuronal populations including neocortical neurones are affected in progressive supranuclear palsy (PSP) and AD. Differences in the molecular composition of PSP-NFTs highlighted by immunochemical studies induce us to speculate that different physio- and aetiopathogenetic mechanisms are operative in the production of PSP-NFTs.

Increase in plasma concentration of ubiquitin in dialysis patients: possible involvement in beta 2-microglobulin amyloidosis

beta 2-Microglobulin(beta 2-M) amyloidosis is a serious complication of dialysis therapy; however, its pathogenesis is still unclear. Recent studies have indicated that ubiquitin has amyloid enhancing factor activity, raising the possibility that ubiquitin plays a role in beta 2-M amyloidogenesis. In this study, synovial tissue from patients with long-term dialysis was examined immunohistochemically. The synovial tissue was labeled with anti-ubiquitin antibody, indicating co-deposition of ubiquitin with beta 2-M amyloid. To elucidate the involvement of plasma ubiquitin, we established a specific radioimmunoassay for ubiquitin. Using this method, we observed that the plasma concentration of ubiquitin-like immunoreactivity in dialysis patients was significantly higher than that in normal subjects. In chronic renal failure patients, the plasma concentration of ubiquitin-like immunoreactivity was also significantly higher than that in normal controls, which finding suggests that a reduction in renal clearance is, at least in part, responsible for the increased plasma concentration of ubiquitin. In dialysis patients, plasma concentrations of ubiquitin-like immunoreactivity in patients with carpal tunnel syndrome, one of the major symptoms of beta 2-M amyloidosis, were significantly higher than those in patients not exhibiting this syndrome. These results suggest a possible involvement of plasma ubiquitin in beta 2-M amyloidosis.

Ubiquitin in neurodegenerative diseases

Immunochemical staining to detect ubiquitin has become an essential technique in evaluating neurodegenerative processes. Age related staining is seen in myelin, in nerve processes in lysosome-related dense bodies, and in corpora amylacea. There is a constant association between filamentous inclusions and the presence of ubiquitin. Intermediate filaments associated with ubiquitin, alpha B crystallin and enzymes of the ubiquitin pathway are the basis of Lewy bodies and Rosenthal fibres, as well as related bodies outside the nervous system. Neurofibrillary tangles in diverse diseases are associated with ubiquitin as are several other tau containing inclusions in both neurones and glia. Inclusions in motor neurones and non-motor cortex characterizing amyotrophic lateral sclerosis (ALS) and certain related forms of frontal lobe dementia can only be readily detected by anti-ubiquitin. Anti-ubiquitin also identifies both filamentous and lysosomal structures in neuronal processes as well as in some swollen neurones. Involvement of ubiquitin-containing elements of the lysosomal system appears important in pathogenesis of prion encephalopathies. Despite great advances in understanding cell biology of the ubiquitin pathway there are as yet few insights into the precise role played by ubiquitin in neuronal disease.

Ubiquitin in cerebral amyloid angiopathy

Immunohistological findings in cerebral blood vessels of 4 cases with cerebral amyloid angiopathy (CAA) were compared with those of 4 Alzheimer's (AD) cases. A panel of antibodies against 2 neurofilament subunits (BF10 and RT97), a microtubule-associated protein (TAU) and ubiquitin were used. CAA cases showed a strong immunoreactivity for ubiquitin in blood vessel wall. Senile plaques (SPs) in CAA cases showed strong ubiquitin positivity but the central amyloid core was negative. AD brains showed immunoreactivity with all antibodies in SPs and neurofibrillary tangles (NFTs); blood vessels were consistently negative for ubiquitin. Control brains showed few SPs and NFTs; these were positive for ubiquitin, but blood vessels were negative. These results indicate that vascular amyloid deposition in CAA and AD may have different pathophysiological mechanisms.

Ubiquitin: its potential significance in murine AA amyloidogenesis

Amyloid enhancing factor (AEF), which has recently been shown to have identity with ubiquitin (Ub), is believed to play a causative role in experimentally induced AA amyloidosis in mice. We have examined the profile of Ub in activated leukocytes and splenic reticulo-endothelial (RE) cells and its relationship with serum amyloid A protein (SAA) and AA amyloid deposits in an alveolar hydatid cyst (AHC)-infected mouse model of AA amyloidosis. Two monospecific antibodies, anti-ubiquitin (RABU) and anti-mouse AA amyloid, were used as immunological probes to localize Ub, SAA, and AA amyloid. In response to AHC infection, the dull and diffuse Ub immunoreactivity in normal mouse leukocytes and RE cells promptly changed to a discrete granular pattern suggesting an increase in the intracellular concentration of Ub and the formation of Ub-protein conjugates. This corresponded to an elevation in SAA levels, SAA uptake by RABU-positive phagocytic cells, co-localization of Ub-SAA immunoreactive splenocytes in the perifollicular areas, and deposition of Ub-bound AA amyloid in the splenic and hepatic tissues. These results suggest that Ub-loaded monocytoid cells may play an important role in the physiological processing of the sequestered SAA into AA amyloid. Aspects of AA amyloidogenesis are discussed in relation to other experimental models in which stress-induced Ub-protein conjugate formation and its transport to lysosomal vesicles have been studied.

Ubiquitin profile and amyloid enhancing factor activity in Alzheimer and 'normal' human brain extracts

Tris-HCl or Laemmli sample buffer extracted frontal lobe and hippocampal samples from normal aged and Alzheimer's disease (AD) subjects were used to determine total ubiquitin (Ub), distribution of monomeric Ub and Ub-protein conjugates and amyloid enhancing factor (AEF) activity using the dot-blot, Western blot and mouse AEF bioassay techniques, respectively. The AD samples, as compared to the normals, demonstrated a 1.7-fold increase in total Ub, elevated levels of Ub-protein conjugates and an appreciably enhanced AEF activity. Many of the hippocampal Ub-protein conjugates were found to be soluble only in the Laemmli sample buffer. The possible roles of elevated Ub levels and of the association of AEF activity with Ub are discussed in regard to pathogenesis of brain amyloidosis.

Amyloid enhancing factor activity is associated with ubiquitin

Crude amyloid enhancing factor (AEF) drastically reduces the pre-amyloid phase on passive transfer and induces amyloid deposition in the recipient mice in 48-120 h. We attempted to purify AEF from murine amyloidotic liver and spleen extracts by using gel filtration, preparative sodium dodecyl sulphate-polyacrylamide gel electrophoresis and ion exchange chromatography and isolated a 5.5 kDa peptide. In the mouse bioassay, this peptide induced accelerated splenic AA deposition in a dose-dependent manner. Based on structural, electrophoretic and immunochemical criteria the peptide was identified as ubiquitin. A polyclonal rabbit anti-bovine ubiquitin IgG antibody (RABU) abolished the in vivo AEF activity of crude murine AEF in a dose-dependent manner. Monomeric ubiquitin and its large molecular weight adducts were isolated from crude AEF using cyanogen bromide-activated sepharose conjugated to RABU and size exclusion chromatography methods. These were assayed and were found to possess AEF activity. Furthermore, increased levels of ubiquitin, a phenomenon similar to that of AEF, were detected by immunocytochemistry in mouse peritoneal leucocytes prior to and during amyloid deposition. Since AEF shares a number of biological and functional properties with ubiquitin, we suggest a possible role of ubiquitin as an AEF, and that serum amyloid protein A and ubiquitin, the two reactants generated during inflammatory stress conditions, may converge to induce AA amyloid deposition.

Age-related ubiquitin deposits in dystrophic neurites: an immunoelectron microscopic study

Widespread neuritic dystrophy is a hallmark of Alzheimer's disease (AD) and, in a less severe form, of brain ageing in various mammalian species. By immunohistochemistry, diffuse dot-like staining for ubiquitin (Ubq), a polypeptide involved in the degradation of abnormal and short-lived proteins, has been associated with human brain ageing. The nature of the Ubq deposits was investigated by immunogold electron microscopy on autopsy samples from aged human and dog brains. Most of the dot-like staining was localized to the white matter and corresponded to myelinated dystrophic neurites filled by Ubq-labelled lysosomal dense bodies. They did not contain paired helical filaments or multilamellar bodies. A minority of Ubq deposits was represented by amorphous densities in focal enlargements of the myelin sheaths. Our findings show that the spectrum of Ubq changes in ageing brain is wider than formerly recognized, and support the hypothesis that a defective regulation of the lysosomal system might be involved in the pathogenesis of structural abnormalities both in the ageing brain and in Alzheimer's disease.

A critical analysis of postulated pathogenetic mechanisms in amyloidogenesis

This review has examined several of the major thrusts in amyloid research, past and present. The data concerning amyloid precursor quantity, primary protein and gene structure, and precursor proteolysis have shown that there are contradictions that must be resolved before these elements can be reamalgamated into a unified view of amyloidogenesis. One possibility is presented in Figure 2. A general hypothesis of amyloid formation that accounts for the uniformity of fibril structure, amyloid staining properties, and the specific selection of precursors and their specific anatomic localization in each form of amyloid has yet to be proposed. Some of these questions may be answered by an analysis of common structural constituents in amyloid deposits. Analyzing amyloid generation in the context of these common elements separates amyloid research into several specific areas (Figure 2). The first area concerns factors that govern the expression of amyloid precursor protein genes, thus providing adequate quantities of the precursor, if such a precursor pool does not already exist. Without such a pool, amyloid deposition clearly cannot occur. The second area concerns information as to where these precursors usually bind and/or exert their normal function. Once determined, this information will likely indicate the site or sites where the particular precursor may give rise to amyloid deposits. The last area concerns factors at these local sites that govern the interaction of the precursor with basement membrane or related extracellular matrix elements that would define both the site and the final common pathway for amyloid deposition.