Identification of two novel amyloid A protein subsets coexisting in an individual patient of AA-amyloidosis

Amyloid A protein (AA), the major fibril protein in AA-amyloidosis, is an N-terminal cleavage product of the precursor protein, serum amyloid A (SAA). Using mass spectrometry and amino-acid sequencing, we identified and characterized two novel AA protein subsets co-deposited as amyloid fibrils in an patient having AA-amyloidosis associated with rheumatoid arthritis. One of the AA proteins corresponded to positions 2–76 (or 75) of SAA2α and the other corresponded to positions 2–76 (or 75) of known SAA1 subsets, except for position 52 or 57, where SAA1α has valine and alanine and SAA1β has alanine and valine in position 52 and 57, respectively, whereas the AA protein had alanine at the both positions. Our findings (1), demonstrate that not only one but two SAA subsets could be deposited together as an AA-amyloid in a single individual and (2), support the existence of a novel SAA1 allotype, i.e., SAA1^52,57Ala.     

Mink serum amyloid A protein. Expression and primary structure based on cDNA sequences

The nucleotide sequences of two mink serum amyloid A (SAA) cDNA clones have been analyzed, one (SAA1) 776 base pairs long and the other (SAA2) 552 base pairs long. Significant differences were discovered when derived amino acid sequences were compared with data for apoSAA isolated from high density lipoprotein. Previous studies of mink protein SAA and amyloid protein A (AA) suggest that only one SAA isotype is amyloidogenic. The cDNA clone for SAA2 defines the "amyloid prone" isotype while SAA1 is found only in serum. Mink SAA1 has alanine in position 10, isoleucine in positions 24, 67, and 71, lysine in position 27, and proline in position 105. Residue 10 in mink SAA2 is valine while arginine and asparagine are at positions 24 and 27, respectively, all characteristics of protein AA isolated from mink amyloid fibrils. Mink SAA2 also has valine in position 67, phenylalanine in position 71, and amino acid 105 is serine. It remains unknown why these six amino acid substitutions render SAA2 more amyloidogenic than SAA1. Eighteen hours after lipopolysaccharide stimulation, mink SAA mRNA is abundant in liver with relatively minor accumulations in brain and lung. Genes encoding both SAA isotypes are expressed in all three organs while no SAA mRNA was detectable in amyloid prone organs, including spleen and intestine, indicating that deposition of AA from locally synthesized SAA is unlikely. A third mRNA species (2.2 kilobases) was identified and hybridizes with cDNA probes for mink SAA1 and SAA2. In addition to a major primary translation product (molecular mass 14,400 Da) an additional product with molecular mass 28,000 Da was immunoprecipitable.     

Serum amyloid A (SAA) activates human mast cells which leads into degradation of SAA and generation of an amyloidogenic SAA fragment

Serum amyloid A (SAA) is a precursor for the amyloid A in AA type of amyloidosis. Distribution of mast cells in tissues is similar to the distribution of amyloid deposits in secondary AA-amyloidosis. Therefore, we studied whether mast cells could be involved in SAA metabolism. Human mast cell line (HMC-1) cells were cultured with recombinant human apoSAA (rhSAA), and the production of tumour necrosis factor (TNF)-alpha and interleukin (IL)-1 beta was determined by ELISA. RhSAA and human SAA (huSAA) were incubated with human chymase, tryptase or with intact human mast cell (huMC) in cultures, and degradation of SAA was followed by gel electrophoresis, liquid chromatography and mass spectrometry. SAA induced dose-dependent production of TNF-alpha and IL-1 beta in HMC-1 cells. Tryptase, chymase, and huMC granules degraded efficiently the SAA protein. Degradation of SAA by tryptase, but not by chymase, released a highly amyloidogenic N-terminal fragment of SAA. Finally, incubation of huMC with rhSAA alone resulted in degradation of SAA and formation of protofibrillar intermediates. These results suggest a pathogenic role for mast cells in AA-amyloidosis.     

Polymorphism of tissue and serum amyloid A (AA and SAA) proteins in the mouse

Amino acid sequence studies of the amino terminal 25 residues of amyloid A (AA) protein and the serum precursor (SAA) induced with casein or LPS indicate differences in the sequence at position 6 and significant heterogeneity at several other positions in SAA. These findings suggest that SAA is a polymorphic serum protein and raise the possibility that only certain forms of SAA are processed to the tissue amyloid fibril.     

Influence of genotypes at SAA1 and SAA2 loci on the development and the length of latent period of secondary AA-amyloidosis in patients with rheumatoid arthritis

To examine whether polymorphism at the SAA loci is associated with the development of amyloid protein A (AA)-amyloidosis, we determined the genotypes at the SAA1 and SAA2 loci in 43 AA-amyloidosis patients (amyloidosis population) and 77 patients with rheumatoid arthritis (RA) who had been ill for less than 5 years (early RA population). We also compared the frequencies of the genotypes at the SAA1 locus among 90 Korean, 95 Taiwanese, and 103 Japanese healthy subjects. The frequencies of the gamma/gamma genotype and gamma alleles at the SAA1 locus were significantly higher in the amyloidosis population than in the early RA population (34.9% versus 7.8%, and 58.1% versus 33.8%, chi2 test P=0.0001). The frequencies of the gamma allele at the SAA1 locus in Koreans, Taiwanese, and Japanese were 41.6%, 35.6%, and 37.4%, respectively. The length of the latent period of AA-amyloidosis was significantly longer in the patients with smaller numbers of the gamma allele at the SAA1 locus (Spearman's correlation coefficient: -0.42, P<0.05). On the other hand, the mean C-reactive protein (CRP) level during 2 years prior to the diagnosis of AA-amyloidosis was significantly higher in the patients with larger numbers of the gamma allele at the SAA1 locus (Spearman's correlation coefficient: 0.34, P<0.05). No significant association was found between amyloidosis and polymorphism at the SAA2 locus. We postulate that the allele SAA1gamma renders an RA patient susceptible to amyloidosis, possibly by affecting the severity of inflammation in RA.     

Accelerated resolution of AA amyloid in heparanase knockout mice is associated with matrix metalloproteases

AA-amyloidosis is a disease characterized by abnormal deposition of serum A amyloid (SAA) peptide along with other components in various organs. The disease is a complication of inflammatory conditions that cause persistent high levels of the acute phase reactant SAA in plasma. In experimental animal models, the deposited amyloid is resolved when the inflammation is stopped, suggesting that there is an efficient clearance mechanism for the amyloid. As heparan sulfate (HS) is one of the major components in the amyloid, its metabolism is expected to affect the pathology of AA amyloidosis. In this study, we investigated the effect of heparanase, a HS degradation enzyme, in resolution of the AA amyloid. The transgenic mice deficient in heparanase (Hpa-KO) produced a similar level of SAA in plasma as the wildtype control (Ctr) mice upon induction by injection of AEF (amyloid enhancing factor) and inflammatory stimuli. The induction resulted in formation of SAA amyloid 7-days post treatment in the spleen that displayed a comparable degree of amyloid load in both groups. The amyloid became significantly less in the Hpa-KO spleen than in the Ctr spleen 10-days post treatment, and was completely resolved in the Hpa-KO spleen on day 21 post induction, while a substantial amount was still detected in the Ctr spleen. The rapid clearance of the amyloid in the Hpa-KO mice can be ascribed to upregulated matrix metalloproteases (MMPs) that are believed to contribute to degradation of the protein components in the AA amyloid. The results indicate that both heparanase and MMPs play important parts in the pathological process of AA amyloidosis.     

The frequencies of the serum amyloid A2 alleles in healthy (Turkish, Azerbaijan and Kazakh) populations

The Amyloid A1 (AA1) and A2 (AA2) proteins, which result from proteolytic cleavage of the Serum Amyloid A1 (SAA1) and A2 (SAA2) proteins, are major protein components of the Amyloid A deposits found in secondary amyloidosis. This study determines frequency of serum amyloid A2 alleles (alpha, beta) in healthy Turkish, Azerbaijan and Kazakh subjects. Two hundred Turkish, sixty five Azerbaijan and sixty five Kazakh healthy individuals were studied by previously described the PCR-RFLP methods. Our data revealed that the frequencies of the alpha and beta alleles at the SAA2 locus in the Turkish healthy population were different when compared to those in Azerbaijan and Kazakh healthy populations (p = 0.014 and p = 0.02), respectively. In contrast, the difference between alpha and beta alleles at the SAA2 locus was not different in both Kazakh and Azerbaijan healthy populations (p = 0.882).     

Primary structures of dog and cat amyloid A proteins: comparison to human AA

1. The complete amino acid sequences of canine and feline amyloid A (AA) proteins were determined and compared with the sequence of human AA protein. 2. The dog and cat AA proteins were 84% homologous with human AA through residue 69. 3. Between the residues which correspond to 69 and 70 in the human sequence, the dog and cat proteins had an insertion of eight amino acids after which homology with human AA resumed. 4. While human AA commonly ends at position 76, the carboxyl termini of dog and cat AA proteins corresponded to position 86 in the sequence of the precursor protein-serum amyloid A. 5. These results are particularly interesting with respect to evolution of the serum amyloid A gene family.     

Proteomic Analysis of Highly Prevalent Amyloid A Amyloidosis Endemic to Endangered Island Foxes

Amyloid A (AA) amyloidosis is a debilitating, often fatal, systemic amyloid disease associated with chronic inflammation and persistently elevated serum amyloid A (SAA). Elevated SAA is necessary but not sufficient to cause disease and the risk factors for AA amyloidosis remain poorly understood. Here we identify an extraordinarily high prevalence of AA amyloidosis (34%) in a genetically isolated population of island foxes (Urocyon littoralis) with concurrent chronic inflammatory diseases. Amyloid deposits were most common in kidney (76%), spleen (58%), oral cavity (45%), and vasculature (44%) and were composed of unbranching, 10 nm in diameter fibrils. Peptide sequencing by mass spectrometry revealed that SAA peptides were dominant in amyloid-laden kidney, together with high levels of apolipoprotein E, apolipoprotein A-IV, fibrinogen-α chain, and complement C3 and C4 (false discovery rate ≤0.05). Reassembled peptide sequences showed island fox SAA as an 111 amino acid protein, most similar to dog and artic fox, with 5 unique amino acid variants among carnivores. SAA peptides extended to the last two C-terminal amino acids in 5 of 9 samples, indicating that near full length SAA was often present in amyloid aggregates. These studies define a remarkably prevalent AA amyloidosis in island foxes with widespread systemic amyloid deposition, a unique SAA sequence, and the co-occurrence of AA with apolipoproteins.     

AA-amyloidosis can be transferred by peripheral blood monocytes

Spongiform encephalopathies have been reported to be transmitted by blood transfusion even prior to the clinical onset. Experimental AA-amyloidosis shows similarities with prion disease and amyloid-containing organ-extracts can prime a recipient for the disease. In this systemic form of amyloidosis N-terminal fragments of the acute-phase reactant apolipoprotein serum amyloid A are the main amyloid protein. Initial amyloid deposits appear in the perifollicular region of the spleen, followed by deposits in the liver. We used the established murine model and induced AA-amyloidosis in NMRI mice by intravenous injections of purified amyloid fibrils ('amyloid enhancing factor') combined with inflammatory challenge (silver nitrate subcutaneously). Blood plasma and peripheral blood monocytes were isolated, sonicated and re-injected into new recipients followed by an inflammatory challenge during a three week period. When the animals were sacrificed presence of amyloid was analyzed in spleen sections after Congo red staining. Our result shows that some of the peripheral blood monocytes, isolated from animals with detectable amyloid, contained amyloid-seed that primed for AA-amyloid. The seeding material seems to have been phagocytosed by the cells since the AA-precursor (SAA1) was found not be expressed by the monocytes. Plasma recovered from mice with AA amyloidosis lacked seeding capacity. Amyloid enhancing activity can reside in monocytes recovered from mice with AA-amyloidosis and in a prion-like way trigger amyloid formation in conjunction with an inflammatory disorder. Human AA-amyloidosis resembles the murine form and every individual is expected to be exposed to conditions that initiate production of the acute-phase reactant. The monocyte-transfer mechanism should be eligible for the human disease and we point out blood transfusion as a putative route for transfer of amyloidosis.     

Serum amyloid A and protein AA: Molecular mechanisms of a transmissible amyloidosis

Systemic AA-amyloidosis is a complication of chronic inflammatory diseases and the fibril protein AA derives from the acute phase reactant serum AA. AA-amyloidosis can be induced in mice by an inflammatory challenge. The lag phase before amyloid develops can be dramatically shortened by administration of a small amount of amyloid fibrils. Systemic AA-amyloidosis is transmissible in mice and may be so in humans. Since transmission can cross species barriers it is possible that AA-amyloidosis can be induced by amyloid in food, e.g. foie gras. In mice, development of AA-amyloidosis can also be accelerated by other components with amyloid-like properties. A new possible risk factor may appear with synthetically made fibrils from short peptides, constructed for tissue repair.     

Acute-phase high-density lipoprotein in the rat does not contain serum amyloid A protein.

Serum amyloid A protein (SAA) is an acute-phase apolipoprotein of high-density lipoprotein (HDL). Its N-terminal sequence is identical with that of amyloid A protein (AA), the subunit of AA amyloid fibrils. However, rats do not develop AA amyloidosis, and we report here that neither normal nor acute-phase rat HDL contains a protein corresponding to SAA of other species. mRNA coding for a sequence homologous with the C-terminal but not with the N-terminal part of human SAA is synthesized in greatly increased amounts in acute-phase rat liver. These observations indicate that the failure of rats to develop AA amyloid results from the absence of most of the AA-like part of their SAA-like protein, and that the N-terminal portion of SAA probably contains the lipid-binding sequences.     

Effect of amino acid variations in the central region of human serum amyloid A on the amyloidogenic properties

Human serum amyloid A (SAA) is a precursor protein of the amyloid fibrils that are responsible for AA amyloidosis. Of the four human SAA genotypes, SAA1 is most commonly associated with AA amyloidosis. Furthermore, SAA1 has three major isoforms (SAA1.1, 1.3, and 1.5) that differ by single amino acid variations at two sites in their 104-amino acid sequences. In the present study, we examined the effect of amino acid variations in human SAA1 isoforms on the amyloidogenic properties. All SAA1 isoforms adopted α-helix structures at 4 °C, but were unstructured at 37 °C. Heparin-induced amyloid fibril formation of SAA1 was observed at 37 °C, as evidenced by the increased thioflavin T (ThT) fluorescence and β-sheet structure formation. Despite a comparable increase in ThT fluorescence, SAA1 molecules retained their α-helix structures at 4 °C. At both temperatures, no essential differences in ThT fluorescence and secondary structures were observed among the SAA1 isoforms. However, the fibril morphologies appeared to differ; SAA1.1 formed long and curly fibrils, whereas SAA1.3 formed thin and straight fibrils. The peptides corresponding to the central regions of the SAA1 isoforms containing amino acid variations showed distinct amyloidogenicities, reflecting their direct effects on amyloid fibril formation. These findings may provide novel insights into the influence of amino acid variations in human SAA on the pathogenesis of AA amyloidosis.     

Serum Amyloid A Complexed with Extracellular Matrix Induces the Secretion of Tumor Necrosis Factor-α by human T-lymphocytes

Summary Serum amyloid A (SAA), an acute-phase reactant, exists naturally as a minor protein in the sera of healthy individuals. However, its levels in sera are increased markedly during various transient and chronic inflammatory diseases, often concomitantly with accumulation at inflicted sites. SAA is synthesized mainly in the liver following the synergistic action of cytokines, mainly tumor necrosis factor-α (TNF-α) and interleukin-1 and-6 (IL-1 and IL-6). It was already shown by us that upon interaction with SAA or amyloid A (AA), the extracellular matrix (ECM) and laminin induced the adhesion of resting human CD4⁺ T-cells in an apparently β₁-integrin-mediated manner. Herein we have shown that the SAA-ECM complex modulates the regulation of cytokine synthesis by human T-lymphocytes. The SAA-ECM complex dramatically enhanced the release of TNF-α by human T-cells in a dose-dependent manner, reaching its maximal effect in the presence of 100 μM recombinant SAA. The SAA domain, responsible for the enhanced release of TNF-α by human T-lymphocytes, is apparently the amyloid A protein (AA, i.e. SAA2-82). Specifically, TNF-α enhanced secretion is mediated through intimate interactions of SAA/AA, with laminin. Thus, the ECM serving as a temporary anchorage site for SAA and AA seems to be involved in regulating TNF-α secretion and the recruitment and accumulation of immunocytes in extravascular, inflammatory compartments.     

Differential expression of the amyloid SAA 3 gene in liver and peritoneal macrophages of mice undergoing dissimilar inflammatory episodes

The three active serum amyloid A (SAA) genes of mice, SAA 1, SAA 2, and SAA 3, are coordinately expressed in liver during acute and chronic inflammatory stimulation and experimental amyloidosis. The genes, primarily SAA 3, are also expressed extrahepatically. The apoprotein SAA 2 is the precursor of the amyloid A (AA) fibril protein that is deposited as insoluble fibrils extracellularly in spleen and other organs when amyloidosis occurs secondarily to inflammation. The exact cause of AA fibril formation is unknown. Amyloid enhancing factor is a high m.w. glycoprotein extracted from amyloidotic organs. Administration of amyloid enhancing factor alters experimental inflammation to bring about accelerated deposition of amyloid A fibrils first in spleen and later in other organs. In this study, hepatic and extrahepatic expression of the SAA genes were compared during accelerated amyloidosis relative to inflammation uncomplicated by amyloidosis. Differences in kinetics and pattern of SAA gene expression by resident peritoneal macrophages and liver were detected during four dissimilar inflammatory episodes. Macrophages expressed the SAA 3 gene solely, and to a greater extent in chronic than in acute inflammation. In accelerated amyloid induction, macrophage SAA 3 expression increased as SAA 1 and SAA 2 expression in liver decreased. However, alpha-1-acid glycoprotein expression remained elevated throughout the course of amyloid induction. The greatly increased expression of the SAA 3 gene by macrophages and decreased expression of the SAA 1 and SAA 2 genes in liver during amyloidosis, suggests that altered SAA gene expression may play a pathogenetic role in experimental amyloid deposition.     

IL-6 plays a critical role in the synergistic induction of human serum amyloid A (SAA) gene when stimulated with proinflammatory cytokines as analyzed with an SAA isoform real-time quantitative RT-PCR assay system

Serum amyloid A (SAA) is known to be a precursor of amyloid A (AA) protein in AA (secondary) amyloidosis and SAA1 to be mainly involved in AA amyloidosis. We established an SAA isoform real-time quantitative RT-PCR assay and found that beta-2 microglobulin is more stable as an internal control than GAPDH and beta-actin for our system. Either IL-6 and IL-1beta or IL-6 and TNFalpha, but not IL-1beta and TNFalpha, induced the synergistic induction of SAA1 and SAA2 genes. Anti-IL-6 receptor monoclonal antibody completely inhibited the synergistic induction of SAA1 and SAA2 during triple stimulation with IL-6, IL-1beta, and TNFalpha, but, IL-1 receptor antagonist or anti-TNFalpha monoclonal antibody was only partially inhibited in HepG2, Hep3B, and PLC/PRF/5 cells. Although the SAA1 promoter has no STAT3 consensus sequence, the JAK2 inhibitor-AG490 reduced SAA1 gene expression to 30%, suggesting the involvement of STAT3. We were able to demonstrate that IL-6 plays a critical role in the synergistic induction of human SAA gene when stimulated with proinflammatory cytokines.     

Extrahepatic production of acute phase serum amyloid A

Amyloidosis is a group of diseases characterized by the extracellular deposition of protein that contains non-branching, straight fibrils on electron microscopy (amyloid fibrils) that have a high content of beta-pleated sheet conformation. Various biochemically distinct proteins can undergo transformation into amyloid fibrils. The precursor protein of amyloid protein A (AA) is the acute phase protein serum amyloid A (SAA). The concentration of SAA in plasma increases up to 1000-fold within 24 to 48 h after trauma, inflammation or infection. Individuals with chronically increased SAA levels may develop AA amyloidosis. SAA has been divided into two groups according to the encoding genes and the source of protein production. These two groups are acute phase SAA (A-SAA) and constitutive SAA (C-SAA). Although the liver is the primary site of the synthesis of A-SAA and C-SAA, extrahepatic production of both SAAs has been observed in animal models and cell culture experiments of several mammalian species and chicken. The functions of A-SAA are thought to involve lipid metabolism, lipid transport, chemotaxis and regulation of the inflammatory process. There is growing evidence that extrahepatic A-SAA formation may play a crucial role in amyloidogenesis and enhances amyloid formation at the site of SAA production.     

Degradation and deposition of amyloid AA fibrils are tissue specific

The complete amino acid sequences of two related AA proteins (Mr 9700 and 5300) derived from thyroid tissue from a patient, NOR, with the autosomal recessive disease familial Mediterranean fever were determined. Heterogeneity found at position 52 indicates these proteins are fragments of two allelic or isotypic SAA precursor molecules similarly degraded at unusual sites and deposited in the thyroid. Degradation appears to be tissue and/or enzyme(s) specific since the carboxy terminus of both fragments is Ala-Ala and is different from other AA amyloid fibrils extracted from various tissues in different patients. Electron micrographic studies reveal these fragments retain the characteristics of native amyloid fibrils under physiological conditions even after exposure to dissociating agents.     

Isolation and partial characterization of SAA-an amyloid-related protein from human serum.

A 12,000 dalton serum amyloid A protein (SAA) has been isolated by chromatography on Sephadex in 10% formic acid. It is similar immunologically to the previously characterized 8500 dalton tissue amyloid A (AA) protein. The results of amino acid analyses, peptide maps, and the identity of the first 11 residues of the SAA and AA proteins support the idea that AA represents the amino terminal fragment of SAA and is derived from it by proteolysis.