Leifur Thorsteinsson

Immune Reactions Associated With Cerebral Amyloid Angiopathy

BACKGROUND AND PURPOSE Cerebral amyloid angiopathy (CAA) occasionally coexists with cerebral vasculitis. An immune system may influence deposition or degradation of the amyloid in cerebral blood vessels. The purpose of this study was to elucidate immune reactions associated with CAA. METHODS In 11 elderly patients with sporadic CAA, 2 patients with Icelandic familial CAA, and 2 patients with CAA and granulomatous angiitis, the cerebrovascular amyloid proteins and infiltrating inflammatory cells were analyzed immunohistochemically. RESULTS In both sporadic CAA (beta-protein amyloid angiopathy) and Icelandic familial CAA (cystatin C amyloid angiopathy), leptomeningeal and cortical vessels were associated with an increase or activation of monocyte/macrophage lineage cells. In the cases of CAA with granulomatous angiitis, the vascular amyloid was of beta-protein and associated with infiltration of many monocyte/macrophage lineage cells, which included multinucleated giant cells containing the amyloid in the cytoplasm as well as T cells composed of CD4+ and CD8+ subsets. Amyloid P component, which was reported to be a common component of amyloid deposits and to prevent phagocytic proteolysis of amyloid fibrils of beta-protein, was negative for the vascular amyloid in a case of CAA with granulomatous angiitis but positive in the others. CONCLUSIONS In both the beta-protein and cystatin C amyloid angiopathies, cerebrovascular amyloid deposition was associated with an increase or activation of monocyte/macrophage lineage cells. Prominent reactions of monocyte/macrophage lineage cells admixed with CD4+ and CD8+ T cells (granulomatous angiitis) were occasionally associated with beta-protein angiopathy. In some of these cases, the absence of amyloid P component might be related to pathogenesis of the granulomatous reaction.

Hereditary cystatin C (γ-trace) amyloid angiopathy of the CNS causing cerebral hemorrhage

Abstract Hereditary CNS amyloid angiopathy occurring in Icelanders is the first human disorder known to be caused by deposition of cystatin C amyloid fibrils in the walls of the brain arteries leading to single or or multiple strokes with fatal outcome. One or more affected members have been verified by histological examination in 8 families containing 127 affected. These originated from the same geographic area. Abnormally low value of cystatin C found in the cerebrospinal fluid of those affected can be used to support or make diagnosis of this disease, also in asymptomatic relatives. By amino acid sequence analysis the amyloid fibrils in the patients are found to be a variant of cystatin C (γ‐trace), a major cysteine proteinase inhibitor. The variant protein has an amino acid substitution (glutamine for leucine) at position 58 in the amyloid molecule. It is postulated that a point mutation has occurred leading to production of amyloidogenic protein causing the disorder.

Immunohistochemical characterization of the amyloid deposits and quantitation of pertinent cerebrospinal fluid proteins in hereditary cerebral hemorrhage with amyloidosis.

Cystatin C, a protein inhibitor of lysosomal cysteine proteinases, was demonstrated by immunohistochemical techniques to be present in the birefringent amyloid deposits of the small arteries in the cerebrum, cerebellum, and leptomeninges of 10 Icelandic individuals with hereditary cerebral hemorrhage with amyloidosis. Specimens from other organs were investigated in one of the patients, and amyloid angiopathy characterized by an immunoreactivity of cystatin C was found in a submandibular lymph node. No immunoreactivity of amyloid fibril protein AA, kappa or lambda immunoglobulin light chain, or prealbumin was observed. Significantly low cerebrospinal fluid concentrations of cystatin C were found in all 9 investigated individuals with hereditary cerebral hemorrhage with amyloidosis. The concentrations of beta 2-microglobulin, albumin, and IgG in the cerebrospinal fluid were within normal limits. Isoelectric focusing showed that cystatin C from the cerebrospinal fluid of 9 patients with hereditary cerebral hemorrhage with amyloidosis had an isoelectric point identical to that of normal individuals. This investigation demonstrates that hereditary cerebral hemorrhage with amyloidosis may be diagnosed by two laboratory methods: immunohistochemical investigation of cystatin C in brain tissue specimens and quantitation of cystatin C in cerebrospinal fluid.

Hereditary cystatin C amyloid angiopathy: genetic, clinical, and pathological aspects.

Hereditary cystatin C amyloid angiopathy (HCCAA) is a rare, fatal amyloid disease in young people in Iceland caused by a mutation in cystatin C, which is an inhibitor of several cysteine proteinases, such as cathepsins S, B, and K. The same mutation in cystatin C, l68Q, has been found in all patients examined so far pointing to a common founder. Most of the families can be traced to a region in the northwest of Iceland, around Breidafjordur bay. Mutated cystatin c forms amyloid, predominantly in brain arteries and arterioles, but also to a lesser degree in tissues outside the central nervous system such as skin, lymph nodes, testis, spleen, submandibular salivary glands, and adrenal cortex. The amyloid deposition in the vessel walls causes thickening of the walls leading to occlusion or rupture and resulting in brain hemorrhage.

The Molecular Pathology of Hereditary Cystatin C Amyloid Angiopathy Causing Brain Hemorrhage

Knowledge about molecular pathology of hereditary cystatin C amyloid angiopathy (HCCAA), also called hereditary cerebral hemorrhage with amyloidosis, Icelandic type, has increased greatly in the last decade. The disorder has an autosomal dominant mode of inheritance and causes fatal brain hemorrhage in normotensive young adults. It is due to a mutation in the gene encoding the cysteine proteinase inhibitor, cystatin C. A single nucleotide is substituted, A for T, in the codon 68, resulting in glutamine replacing leucine in the protein sequence. This variant protein has an increased tendency to aggregate and forms heavy depositions of amyloid in the walls of the small arteries and arterioles of the brain. The amyloid deposition leads to arterial damage with single or multiple strokes. In the following review the clinical features, family studies, pathology, biochemistry and molecular genetics of HCCAA are addressed.

Co-localization of β/A4 and cystatin C in cortical blood vessels in Dutch, but not in Icelandic hereditary cerebral hemorrhage with amyloidosis

Based on the recent discovery of co‐localization of β/A4 and cystatin C in cortical blood vessels of patients with cerebral hemorrhages due to sporadic amyloid angiopathy and patients with Alzheimers disease we investigated the presence of these two proteins in the cortical blood vessels of patients suffering from hereditary cerebral hemorrhage with amyioidosis of the Dutch (n = 11) and the Icelandic (n = 2) type. The brains of three patients with sporadic cerebral amyloid angiopathy were also investigated. Blood vessels of the Dutch patients clearly showed immunostaining with β/A4 as well as with cystatin C antibodies, whereas the blood vessels of Icelandic patients showed only staining with cystatin C. In one of the three sporadic amyloid angiopathy patients co‐localization was shown as well. The co‐localization of mutated β/A4 with normal cystatin C in the Dutch patients suggests that cystatin C deposition occurs secondarily to β/A4 deposition. This is probably also the case in sporadic amyloid angiopathy and Alzheimers disease. Cystatin C deposition may play a role in the development of cerebral hemorrhages and leukoencephalopathy.

Microvascular degeneration in hereditary cystatin C amyloid angiopathy of the brain

Hereditary cystatin C amyloid angiopathy (HCCAA), an autosomal dominant form of cerebral amyloid angiopathy (CAA) occurring primarily in Iceland, is characterized by a variant cystatin C amyloid deposition in the walls of cerebral parenchymal and leptomeningeal vessels. Cystatin C is also found to colocalize with amyloid ß/A4 protein in cerebral vessel walls of patients with Alzheimers disease (AD), sporadic CAA, and hereditary cerebral hemorrhage with amyloidosis, Dutch type (HCHWA‐D). The abundance of cystatin C deposition in cerebral blood vessel walls suggests that cellular elements of the vessel wall itself may play a role in its deposition. Microvascular changes in the brains of HCCAA patients were investigated by single‐ and double‐label immunohistochemistry. We found that cystatin C amyloid immunoreactivity was present not only in cerebral cortical and leptomeningeal vessels, but also in white matter parenchymal vessels. Cystatin C deposition was more prominent in the media of parenchymal vessels and in the adventitia of leptomeningeal vessels. Smooth muscle (sm) cells were few or could not be identified within vessel walls showing extensive cystatin C deposition, suggesting progressive loss of these cells as cystatin C accumulates. However, in less severely affected vessels, cystatin C was present in cells that also had the phenotype of sm, suggesting that sm cells synthesize or process cystatin C. Cystatin C immunoreactivity was in addition, detected in some neuronal cell bodies throughout the cortex in patients with HCCAA and AD‐related CAA. Our results indicate that cellular components of the vessel walls may play an important role in cystatin C deposition, as they do in β/A4 deposition in AD‐related CAA. Cystatin C deposition within the vascular media and adventitia, with associated vessel wall injury as manifested by sm cell loss, represents microvascular degeneration that leads to cerebral hemorrhage.

Inflammatory Cytokines in Relation to Adrenal Response Following Total Hip Replacement

Our objective was to investigate the initiation and course of pro‐ and anti‐inflammatory cytokines in early inflammatory response and to elucidate the cytokine system in relation to the adrenal response caused by stress. Seven blood samples were collected, pre‐ and postoperatively (0–72 h) after total hip replacement (THR) due to osteoarthritis. The following cytokines were measured using Cytometric Bead Array: interleukin‐1β (IL‐1β), IL‐6, tumour necrosis factor‐α, IL‐8, IL‐12 and IL‐10 (B&D). Thirteen patients took part in the study (67 ± 9 years). C‐reactive protein increased from <6 to over 200 mg/l on the second post‐op day. The concentration of IL‐6 increased 10‐fold just 3 h post‐op (4–47 pg/ml) and reached its maximum value 6 h post‐op (77 pg/ml; Wilcoxon test P < 0.01) Repeated measurements were also significant (Friedman P < 0.05). The concentration of IL‐8 doubled the day of surgery but did not reach a significant level (Friedman test =0.069). None of the other cytokines showed any significant changes. The diurnal cortisol rhythm was interrupted after the surgery and there was a significant correlation between the cortisol secretion and IL‐6 response. This study demonstrates an isolated elevation in IL‐6 levels with only a minor elevation in IL‐8 following THR. This pro‐inflammatory response seemed to decline without activation of anti‐inflammatory cytokines (IL‐10), but cortisol seemed to play a complicated role in halting the acute inflammatory response.

On the role of monocytes/macrophages in the pathogenesis of central nervous system lesions in hereditary cystatin C amyloid angiopathy

The pathogenesis of the deposition of a variant cystatin C as amyloid in hereditary cystatin C amyloid angiopathy (HCCAA) is not known. To address this question the synthesis and secretion of cystatin C in cultured monocytes from 9 carriers of the mutated cystatin C gene (5 symptomatic and 4 asymptomatic) was examined. The quantity of cystatin C in cells and supernatants was determined by the ELISA method, Western blots were done and selected samples immunostained for cystatin C. Monocytes from individuals carrying the gene defect synthesized cystatin C that was apparently not truncated, a form found in the cerebral amyloid deposits in HCCAA, but showed a distinctly lower rate of cystatin C synthesis than monocytes from healthy controls. The main difference was that the quantity of cystatin C was significantly lower in the supernatants in monocyte cultures from carriers of the gene defect than from healthy controls, possibly due to a partial block in its secretion. This abnormal processing of the cystatin C could explain the low cerebrospinal fluid levels of cystatin C in HCCAA and might be a part of the pathogenetic pathway of amyloid deposition. Furthermore it could, through a lower extracellular concentration of this inhibitor of cysteine proteinases, contribute to destruction of the amyloidotic blood vessels, leading to the most serious clinical manifestation in HCCAA, intracerebral hemorrhage.

Gene expression analysis of hematopoietic progenitor cells identifies Dlg7 as a potential stem cell gene

Inducible hematopoietic stem/progenitor cell lines represent a model for studying genes involved in self‐renewal and differentiation. Here, gene expression was studied in the inducible human CD34+ acute myelogenous leukemia cell line KG1 using oligonucleotide arrays and suppression subtractive cloning. Using this approach, we identified Dlg7, the homolog of the Drosophila Dlg1 tumor suppressor gene, as downregulated at the early stages of KG1 differentiation. Similarly, Dlg7 was expressed in normal purified umbilical cord blood CD34+CD38− progenitors but not in the more committed CD34+CD38+ population. Dlg7 expression was not detected in differentiated cells obtained from hematopoietic colonies, nor was expression detected in purified T‐cells, B‐cells, and monocytes. When analyzed in different types of stem cells, Dlg7 expression was detected in purified human bone marrow‐derived CD133+ progenitor cells, human mesenchymal stem cells, and mouse embryonic stem (ES) cells. Overexpression of Dlg7 in mouse ES cells increased their growth rate and reduced the number of EBs emerging upon differentiation. In addition, the EBs were significantly smaller, indicating an inhibition in differentiation. This inhibition was further supported by higher expression of Bmp4, Oct4, Rex1, and Nanog in EBs overexpressing Dlg7 and lower expression of Brachyury. Finally, the Dlg7 protein was detected in liver and colon carcinoma tumors but not in normal adjacent tissues, suggesting a role for the gene in carcinogenesis. In conclusion, our results suggest that Dlg7 has a role in stem cell survival, in maintaining stem cell properties, and in carcinogenesis.