Purification, identification and profiling of serum amyloid A proteins from sera of advanced-stage cancer patients

Surface-enhanced laser desorption/ionization time of flight mass spectrometry (SELDI-TOF-MS) is a powerful tool for screening potential biomarkers of various pathological conditions. However, low resolution and mass accuracy of SELDI-TOF-MS remain a major obstacle for determination of biological identities of potential protein biomarkers. We report here a refined workflow that combines ZipTip desalting, acetonitrile precipitation, high-performance liquid chromatography (HPLC) separation and matrix-assisted laser desorption/ionization time of flight mass spectrometry (MALDI-TOF-MS) analysis for the profiling, purification and identification of the targeted serum proteins found by SELDI-TOF-MS. By using this workflow, we purified ten targeted proteins from the sera of patients with various types of advanced stage (stage III–IV) cancers. These proteins were identified as isoforms of the human serum amyloid protein A (SAA) family with or without truncations at their N-terminals. This was confirmed by Western blot analysis. Different SAA expression patterns were observed by MALDI-TOF-MS profiling. SAA has long been reported as a biomarker for various cancer types such as lung cancer, ovarian cancer, and breast cancer. However, in this study we found increased SAA expression in the sera of advanced-stage cancer patients with different cancer types. Our results suggest that maybe SAA should not be used alone as a biomarker for any specific cancer type.

Analyses of intricate kinetics of the serum proteome during and after colon surgery by protein expression time series

Monitoring changes in serum protein expression in response to acute events such as trauma, infection or drug intervention may reveal key proteins of great value in predicting recovery or treatment response. Concerted actions of many proteins are expected. Proteins sharing similar expression changes may function in the same physiological process. As a model we analyzed expression changes in serum of colon cancer patients, before, during, and after laparoscopic colon resection. Eight samples were taken from each of four patients before, during, and up to 5 days after surgery. Total serum and a low molecular weight fraction were analyzed by SELDI-TOF-MS. In total 146 masses were detected. A principal components analysis (PCA) illustrates the temporal variation in the postsurgery proteome. Time series for each mass could be clustered into four distinct groups based on similarity in expression pattern. Two masses of 11.4 and 11.6 kDa, part of a slow response cluster, were identified as forms of the acute phase protein serum amyloid A (SAA). Fourteen more proteins belong to this cluster and may also function in acute phase response. We present an approach to analyze temporal variation in the proteome. This approach may be useful to evaluate surgical, nutritional, and pharmacological interventions.

Targeted protein quantitation and profiling using PVDF affinity probe and MALDI-TOF MS

Development of a rapid, effective, and highly specific platform for target identification in complex biofluids is one of the most important tasks in proteomic research. Taking advantage of the natural hydrophobic interaction of PVDF with probe protein, a simple and effective method was developed for protein quantitation and profiling. Using antibody-antigen interactions as a proof-of-concept system, the targeted plasma proteins, serum amyloid P (SAP), serum amyloid A (SAA), and C-reactive protein (CRP), could be selectively isolated and enriched from human plasma by antibody-immobilized PVDF membrane and directly identified by MALDI-TOF MS without additional elution step. The approach was successfully applied to human plasma for rapid quantitation and variant screening of SAP, SAA, and CRP in healthy individuals and patients with gastric cancer. The triplexed on-probe quantitative analysis revealed significant overexpression of CRP and SAA in gastric cancer group, consistent with parallel ELISA measurements and pathological progression and prognostic significance reported in previous literatures. Furthermore, the variant mass profiling of the post-translationally modified forms revealed a high occurrence of de-sialic acid SAP in patients with gastric cancer. Due to the versatile assay design, ease of probe preparation without chemical synthesis, and compatibility with MALDI-TOF MS analysis, the methodology may be useful for target protein characterization, functional proteomics, and screening in clinical proteomics.

Identification of lipopolysaccharide-binding proteins in porcine milk

Septicemia and endotoxemia initiated by bacterial lipopolysaccharide (LPS) are relatively common in suckling and weaned piglets. Maternal milk is a source of both nutrition and immune protection for piglets. Passive transfer of colostral antibodies is necessary for protection of neonatal piglets against diseases, but the concentration of immunoglobulins in milk rapidly declines during the 1st wk of lactation in all mammals. We hypothesized, therefore, that nonimmunoglobulin substances in milk contribute to the innate protection of neonates against septicemia during the suckling period. Using LPS-affinity chromatography for isolation of LPS-binding proteins and liquid chromatography-mass spectrometry for their identification, we identified in porcine milk the following proteins with LPS-binding capacity: lactoferrin, soluble CD14, serum amyloid A, alpha-S1 casein, beta-casein, and kappa-casein. For lactoferrin, alpha-S1 casein, and kappa-casein, in vitro pepsin digestion did not inhibit LPS-binding activity, whereas combined digestion with pepsin and pancreatin abolished it. The biologic functions of these LPS-binding proteins and peptides were not determined.

Purification and separation of hydrophobic serum amyloid A precursor isoforms by a one-step preparative method

The levels of two major serum amyloid A precursor isoforms, SAA1 and SAA2, which are associated with high-density lipoproteins (HDL) are increased during inflammation. The hydrophobic character and the small size difference--corresponding to just 0.8 kDa--between these two members of the SAA family hinder their separation and purification on a large scale by conventional methods. In the current work, both mouse SAA proteins were purified from HDL-SAA and acute-phase serum within 10 h in a one-step procedure using the high-resolution, continuous-elution preparative gel electrophoresis Prep-Cell system in combination with Tris/Glycine SDS-PAGE. Moreover, applying the Tris/Tricine system on the Prep-Cell resulted not only in purification of the SAA proteins, but also in their separation within 16 h. The SAA isoforms were freed from SDS using a Centricon concentrator and were identified using monoclonal antibodies. Optical density profile plots of gel protein or Western blot bands in combination with a colorimetric spectrophotometric protein assay showed that the recovery of the isoforms ranged from 38% to 60%. These results show that the preparative gel electrophoresis system Prep-Cell is a suitable device for separating SAA1 and SAA2 proteins in a simplified, convenient, and fast procedure, which can be applied on a small or large scale.

Purification of amyloid protein AA subspecies from amyloid-rich human tissues

Protein AA, the major amyloid fibril protein in reactive (secondary) systemic amyloidosis is derived from the acute phase reactant liver-produced apolipoprotein serum AA (SAA) by proteolytic cleavage, usually in the C-terminal half of the 104 amino acid residues long precursor. The cleavage points in SAA vary between patients and the deposited protein AA is often quite heterogeneous. In this chapter, we describe methods to extract amyloid fibrils and to purify protein AA by sequential gel filtration. Further purification of subspecies of protein AA is best achieved by the use of differences in charge and chromatofocusing is described as the method of choice. Analytic methods include sodium dodecylsulfate polyacrylamide gel electrophoresis and analytic isoelectric focusing.

Enrichment of serum amyloid proteins by hydrophobic interaction chromatography combined with two-dimensional electrophoresis with immobilised pH gradients

Serum amyloid A protein was subjected to one-step octyl-Sepharose extraction in three different dimensions. Elution was performed partly without UV recording, and with urea or guanidine-based buffers. The eluent was applied directly to denaturing two-dimensional electrophoresis with immobilised pH gradient, or octyl-Sepharose extracted fractions were pooled and lyophilised before application. Proteins were characterised by N-terminal analysis or mass spectrometry. In most of the species that were studied, previously undescribed serum amyloid proteins were detected. Compared to conventional strategies, the presented techniques are more rational and yield more comprehensive information. The presented data also provide a basis for novel perspectives regarding certain inflammatory conditions.

Elevated extrahepatic expression and secretion of mammary-associated serum amyloid A 3 (M-SAA3) into colostrum

Mammary-associated serum amyloid A 3 (M-SAA3) was secreted at highly elevated levels in bovine, equine and ovine colostrum and found at lower levels in milk 4 days postparturition. N-terminal sequencing of the mature M-SAA3 protein from all the three species revealed a conserved four amino acid motif (TFLK) within the first eight residues. This motif has not been reported to be present in any of the hepatically-produced acute phase SAA (A-SAA) isoforms. Cloning of the bovine M-Saa3 cDNA from mammary gland epithelial cells revealed an open reading frame that encoded a precursor protein of 131 amino acids which included an 18 amino acid signal peptide. The predicted 113 residue mature M-SAA3 protein had a theoretical molecular mass of 12,826Da that corresponded with the observed 12.8kDa molecular mass obtained for M-SAA3 in immunoblot analysis. The high abundance of this extrahepatically produced SAA3 isoform in the colostrum of healthy animals suggests that M-SAA3 may play an important functional role associated with newborn adaptation to extrauterine life and possibly mammary tissue remodeling.

Proteolysis of AA amyloid fibril proteins by matrix metalloproteinases-1, -2, and -3

We recently demonstrated the presence of matrix metalloproteinases (MMPs)-1, -2, and -3 in AA amyloid deposits, which lead us to speculate that MMPs may participate in amyloidogenesis by either processing the precursor protein, or by degrading the amyloid deposits. Here we investigated this theory by determining the ability of MMP-1, -2, and -3 to degrade human acute-phase serum amyloid A (SAA) and human AA amyloid fibril proteins (AFPs). The following in vitro degradation experiments were performed: using either recombinant MMP-1, -2, or -3 and SAA as a substrate; using either recombinant MMP-1, -2, or -3 and AFP as a substrate; and using THP-1 cells as the protease source and AFP as the substrate. All three MMPs were able to cleave SAA and AFP within the region spanning residues 51 to 57. The following cleavage sites were identified: at 57 to 58 for MMP-1; at 7 to 8 and 51 to 52 for MMP-2; at 7 to 8, 16 to 17, 23 to 24, 51 to 52, 55 to 56, 56 to 57, and 57 to 58 for MMP-3. Cell culture experiments showed that THP-1 cells were able to degrade AFPs. Degradation was significantly delayed after addition of a general metalloproteinase inhibitor (o-phenanthroline) to dextran sulfate-stimulated cells. This is the first study to show that human SAAs and AFPs are susceptible to proteolytic cleavage by MMPs. Immunocytochemistry and electron microscopy showed that degradation takes place in the pericellular or extracellular compartment.

Serum amyloid A (apoSAA) expression is up-regulated in rheumatoid arthritis and induces transcription of matrix metalloproteinases

The acute-phase reactant rabbit serum amyloid A 3 (SAA3) was identified as the major difference product in Ag-induced arthritis in the rabbit, a model resembling in many aspects the clinical characteristics of rheumatoid arthritis (RA) in humans. In Ag-induced arthritis, up-regulated SAA3 transcription in vivo was detected in cells infiltrating into the inflamed joint, in the area where pannus formation starts and, most notably, also in chondrocytes. The proinflammatory cytokine IL-1beta induced SAA3 transcription in primary rabbit chondrocytes in vitro. Furthermore, rSAA3 protein induced transcription of matrix metalloproteinases in rabbit chondrocytes in vitro. In the human experimental system, IL-1beta induced transcription of acute-phase SAA (A-SSA; encoded by SAA1/SAA2) in primary chondrocytes. Similar to the rabbit system, recombinant human A-SAA protein was able to induce matrix metalloproteinases' transcription in chondrocytes. Further, immunohistochemistry demonstrated that A-SAA was highly expressed in human RA synovium. A new finding of our study is that A-SSA expression was also detected in cartilage in osteoarthritis. Our data, together with previous findings of SAA expression in RA synovium, suggest that A-SAA may play a role in cartilage destruction in arthritis.

A non-competitive chemiluminescence enzyme immunoassay for the equine acute phase protein serum amyloid A (SAA) -- a clinically useful inflammatory marker in the horse

A non-competitive chemiluminescence enzyme immunoassay for measuring serum amyloid A (SAA) in equine serum was developed. A polyclonal anti-equine-amyloid A antiserum specific for equine SAA was utilized, and the assay was standardized using highly purified equine SAA. An acute phase horse serum was calibrated against the purified SAA and was used as standard when running the assay. Serum SAA concentrations in the range of 3-1210 mg/l could be measured. The reference range of SAA in clinically healthy adult horses was <7 mg/l. The clinical validation of the assay comprised the SAA responses after surgery and experimentally induced aseptic arthritis, and those associated with viral and bacterial infections. The SAA response after surgery (castration) was consistent, with peak concentrations on day 2 and a return to normal SAA concentrations within eight days. The aseptic arthritis produced an SAA response with a pattern similar to that seen after surgery, with peak concentrations of SAA 36-48 h after induction. Seven horses showed a biphasic pattern, with a second rise in SAA concentrations on day 4 and 5. All animals had SAA levels <7 mg/l on day 15. All horses with viral and bacterial infections had SAA concentrations above 7 mg/l. The ranges of SAA concentrations following the different types of inflammation overlap, being consistent with the unspecific nature of the SAA response. This study revealed that SAA is a sensitive and unspecific marker for inflammation, and describes the dynamics of the SAA response after standardized and well defined tissue damage.

N-terminal sequence analysis of SAA-derivatives purified from murine inflammatory macrophages

The pathogenesis of secondary amyloidosis in vivo is not well-understood. Experimental studies suggest that incomplete degradation of acute phase serum amyloid A (SAA), presumably endocytosed by activated monocytoid cells, may lead to intralysosomal formation of amyloid A (AA). To establish a possible link between these two events, we have carried out partial N-terminal sequence analysis of affinity purified SAA derivatives from peritoneal macrophages isolated at 4 weeks post-infection from alveolar hydatid cyst infected C57BL/6 mice. The macrophage lysates yielded five N-terminally intact SAA derivatives of approximately 5 to approximately 12 kDa which reacted with anti-mouse AA IgG, and contained a mixture of SAA1 and SAA2 isoforms. The SAA2:SAA1 ratio, evaluated from their proportion present in each M(r) SAA derivative, showed a decrease with the decreasing apparent mass of the N-terminally infected SAA material. These results not only confirm that both SAA1 and SAA2 are processed by activated monocytoid cells but, more importantly, establish a plausible link between N-terminally intact SAA derivatives and formation of AA within activated monocytoid cells.

A high resolution ultrastructural comparison of isolated and in situ murine AA amyloid fibrils

There is an inconsistency between the ultrastructural organization of AA amyloid fibrils that have been isolated, which are composed of a slowly twisting set of two or more protofibrils, and those seen in situ, which are tubular entities with a tight helical substructure. In this study, the ultrastructure of fibrils isolated from experimental murine AA amyloid were observed at high resolution and compared with those seen in situ in the hope of clarifying the reason for this inconsistency. The fibrils in situ were composed of a microfibril-like 8-9 nm wide core covered by a layer of heparan sulfate proteoglycan (HSPG) to which 1 nm wide filaments, immunohistochemically identified as AA protein, were externally associated. Following isolation with the standard distilled water washing procedure, the HSPG layer and AA protein filaments detached from their core and dispersed into the water. The remaining denuded, variously loosened cores lost their typical appearance. In distilled water the detached 1 nm wide AA protein filaments became quite conspicuous and coiled themselves into 3 nm wide tight helices which in turn assembled into the characteristic slowly twisting sets of two parallel protofibrils similar to that previously reported as "isolated amyloid fibrils". The results emphasize that great caution must be taken in extrapolating amyloid fibril structure from isolated preparations to in situ tissue conditions.

The presence of two low molecular mass proteins immunologically related to 14 kilodalton serum amyloid A in the lipoprotein fraction and their decreased serum concentrations in calves with experimentally induced pneumonia

A 14 kilodalton (kDa) serum amyloid A (apoSAA) protein was purified from cow serum. Rabbit antiserum to the 14 kDa apoSAA recognized, in addition to the 14 kDa protein, a 7.5-9.0 kDa protein and a protein having a molecular mass of less than 6.5 kDa (< 6.5 kDa protein). The possibility that the two proteins were contaminants was excluded by results showing that the two proteins detected in early stages of purification procedures were not found in the purified 14 kDa apoSAA fraction, as revealed by immunoblot analysis. As in the 14 kDa apoSAA, the 7.5-9.0 kDa protein was localized in the high-density lipoprotein fraction, while the < 6.5 kDa protein was in the low-density lipoprotein fraction. In calves with pneumonia induced by inoculation to the lungs of Pasteurella haemolitica, the serum concentration of the 14 kDa apoSAA was increased, whereas those of the 7.5-9.0 kDa and the < 6.5 kDa proteins were conversely decreased. The time-course study indicated that the increase in concentration of the 14 kDa apoSAA and decrease in that of the < 6.5 kDa protein occurred almost simultaneously. These results suggest that the 14 kDa apoSAA and the immunologically related 7.5-9.0 kDa and < 6.5 kDa proteins act as positive and negative acute phase reactants, respectively, and also that concentrations of the three proteins are regulated in concert in acute phase plasma.

Mouse serum amyloid A (SAA) proteins isolated by two-dimensional electrophoresis: characterization of isotypes and the effect of separate and combined administrations of cytokines, dexamethasone and lipopolysaccharide (LPS) on serum levels and isotype distribution

Hydrophobic interaction chromatography and two-dimensional electrophoresis were used to isolate and characterize mouse SAA, and to study the in vivo effect of separate or combined administrations of cytokines, dexamethasone (DEX) and LPS on mouse SAA. Four SAA spots containing partial amino acid sequence in accordance with mouse apoSAA and apoSAA2/SAA(SJL/J) pI 5.9 were demonstrated in serum. One of these proteins represents a previously undescribed, acidic acute-phase mouse SAA protein. Both DEX and interferon-gamma (IFN-gamma) proved to be capable of increasing SAA serum levels. In contrast to what has been shown in previous in vivo studies, administration of IL-6 did increase the SAA levels to nearly the same magnitude as IL-1, and the effect of IL-6 and LPS on SAA production was not significantly altered by the addition of DEX. Irrespective of the inflammatory stimuli that was administered, a non-selective production of SAA1 and SAA2 was observed in most groups, including the group that received IL-6. The results illustrate that data obtained about mouse SAA are highly dependent on which models, isolation and identification methods are used.

Isolation and purification of two major serum amyloid A isotypes SAA1 and SAA2 from the acute phase plasma of mice

A new procedure was developed for isolation of two major serum amyloid A (SAA) isotypes SAA1 and SAA2 from acute-phase plasma of mice. The procedure included preparation of high-density lipoproteins (HDLs) and their separation by sodium dodecyl sulphate polyacrylamide gel electrophoresis (SDS-PAGE). The SAA proteins (Mr 12,000) were electroeluted and afterwards purified from SDS by gel permeation chromatography on a Fractogel TSK-40F column in aqueous 50% acetonitrile-0.1% TFA. Finally, the SAA proteins free from SDS were fractionated by high-performance liquid chromatography on a Vydac 214TP54 column (250 x 4.6 mm I.D., particle size 5 microm), yielding two major fractions with k=5.2 and k=5.5. The N- and C-terminal sequence analyses and mass spectrometry demonstrated the purity of these two major fractions and their identity with apo SAA1 (k=5.2) and apo SAA2 (k=5.5). The developed procedure is applicable to small amounts of pooled murine plasma (6-7 ml) and could be readily modified from small to large scale preparations.

The acute phase serum amyloid A protein (SAA) in the horse: isolation and characterization of three isoforms

Serum amyloid A (SAA) from acute phase horse serum was isolated using hydrophobic interaction chromatography, gel filtration and ion exchange chromatography. Three SAA isoforms with different isoelectric points, i.e. SAA pI 8.0, SAA pI 9.0 and SAA pI 9.7, were identified by two-dimensional electrophoresis and further characterized with amino acid sequence analysis. These isoforms were found in similar concentrations in all animals investigated, with SAA pI 9.7 constituting about half of the total SAA content. Partial amino acid sequence analysis verified the previously published heterogeneous SAA sequence. SAA pI 8.0 was found to have isoleucine in Position 16, glutamine in Position 44 and glycine in Position 59. SAA pI 9.0 had leucine, glutamine and alanine in the corresponding positions. In SAA pI 9.7 leucine, lysine and alanine were detected. The three isoforms characterized in this study are all acute phase SAAs. SAA pI 9.0 and 9.7 correspond to amyloid A protein variants previously isolated from amyloid deposits of equine liver, while there are no reports on an amyloid A variant corresponding to SAA pI 8.0.

Acute phase proteins in salmonids: evolutionary analyses and acute phase response

Inflammation induces dramatic changes in the biosynthetic profile of the liver, leading to increased serum concentrations of positive acute phase (AP) proteins and decreased concentrations of negative AP proteins. Serum amyloid A (SAA) and the pentraxins C-reactive protein (CRP) and serum amyloid P component (SAP) are major AP proteins: their serum levels can rise by 1000-fold, indicating that they play a critical role in defense and/or the restoration of homeostasis. We have cloned SAA and a SAP-like pentraxin from salmonid fish species. The salmonid SAA shares approximately 70% amino acid identity with mammalian AP SAA. When salmonids are challenged with an AP stimulus, i.e., Aeromonas salmonicida, SAA responds dramatically as a major AP reactant. The salmonid pentraxin shows approximately 40% amino acid identity to both mammalian SAP and CRP. Evolutionary analysis suggests the presence of only a single such protein in teleosts and lower animal species. Surprisingly, the salmonid pentraxin behaves as a negative AP reactant, reminiscent of the SAP-like Syrian hamster female protein, in that hepatic mRNA concentrations decline to 50% of prestimulus levels. This study reinforces the hypothesis that SAA induction is an essential and universal feature of the vertebrate AP response and that it represents part of an ancient host defense system. Conversely, the species-dependent heterogeneity of pentraxin expression during the vertebrate AP response supports the possibility that its most important ancestral (and perhaps present) function is not related to its AP behavior.

Isolation of serum amyloid A protein by small-scale hydrophobic interaction chromatography and two-dimensional electrophoresis

A recently introduced technique to isolate serum amyloid A protein is hydrophobic interaction chromatography combined with two-dimensional electrophoresis with immobilized pH gradients. A modification of the original version of this technique is presented. Mouse serum was subjected to hydrophobic interaction chromatography on a small scale, and the eluate was applied directly to two-dimensional electrophoresis. Simple electropherogramss with optimal resolution of serum amyloid A protein were obtained. The presented technique facilitates isolation of serum amyloid A protein from small blood volumes, and might also be adapted to alternative applications.

Alveolar hydatid cyst (AHC): inflammation-induced reactive gastrointestinal (GL) amyloidosis in AHC-infected mice and chemical characterization of the GL amyloid

A high incidence of GI amyloidosis has been described in patients with various forms of systemic amyloidosis but its evolution and progression in different subregions of the GI tract are not well documented. These aspects including the chemical nature of GI amyloid were examined in the AHC mouse model of inflammation-associated reactive amyloidosis. C57BL/6 mice were infected intraperitoneally with 250 AHC. Paraffin sections from the stomach and the small and large intestines of AHC mice were stained at different time intervals with Congo red or immunocytochemically with monospecific RAA. The submucosal blood vessels at 1 week postinfection were found to be the first target of amyloid deposition. With time the amyloid deposits extended to the mucosa and the Peyer's patches and immunoreacted with RAA; ileum was the most severely affected region. Amyloid was extracted from the GI tract and purified by size exclusion chromatography using 5 M guanidine-formic acid, pH 3. The purified amyloid was identified by Western blotting using RAA and by partial N-terminal microsequencing up to 10 cycles. The GI amyloid showed homology with murine SAA2, although SAA2 mRNA is not expressed in murine GI tract. These results shows that (a) the GI amyloid is derived, similar to that of splenic/hepatic amyloid, from circulating SAA2 and (b) the GI tract submucosal blood vessels are the first target of AA deposition. The data also suggest that AA-mediated damage to the submucosal blood capillaries may lead to SAA leakage followed by cascading of AA deposition in other layers of the GI tract.

Wallaby serum amyloid A protein: cDNA cloning, sequence and evolutionary analysis

A serum amyloid A (SAA) clone was isolated from a Tammar wallaby cDNA library, the most distantly related mammalian species for which an SAA has been described to date. The clone predicts a premolecule of 127 amino acids with good homology to other mammalian SAAs, and consists of an 18 residue leader peptide and a mature protein of 109 amino acids. Evolutionary analysis at both the protein and nucleotide level indicate that the wallaby SAA clone clusters with the acute phase SAAs. However, as the SAA superfamily has undergone concerted evolution it is not possible to determine at this point which acute phase SAA it is most like. The grouping of wallaby SAA inside the acute phase SAA cluster demonstrates that at least some of the duplication events giving rise to multiple acute phase genes occurred prior to the divergence of the eutherian and metatherian mammals.

Both murine SAA1 and SAA2 yield AA amyloid in alveolar hydatid cyst-infected mice

Amyloid susceptible C57BL/6 and partially amyloid resistant A/J mice, infected intraperitoneally with 250 alveolar hydatid cyst (AHC), the larval stage of a cestode parasite Echinococcus multilocularis, develop multiple organ amyloid deposits at approximately 1 and 4 weeks post infection (p.i.), respectively. Pooled spleens and livers from each mouse strain, at 8 and 10 weeks p.i., were used for the purification of protein AA utilizing a HiLoad Superdex 200 column equilibrated with 5 M guanidine-HCl. Protein AA from each mouse strain was separated on 16% Tris-tricine SDS-PAGE gels and immunoblotted with monospecific rabbit anti-mouse AA IgG; five and six immunoreactive AA subspecies were detected in the C57BL/6 and A/J materials, respectively. N-Terminal amino acid sequence analysis was performed on the bulk column-purified protein AA as well as on the electroblotted AA subspecies from each mouse strain. The results show a mixture of serum amyloid A1 (SAA1) and (SAA2)-derived AA protein from each mouse strain; SAA1-derived AA, although alluded to, has never been demonstrated as tissue deposits in mice. These findings suggest that the intense and persistent inflammatory processes in AHC-infected mice may have induced conversion of weakly amyloidogenic SAA1 to AA. This conversion could be detected by amino acid sequencing of electrophoretically separated AA subspecies.

Chicken joint amyloid protein is of the AA-type. I. Characterization of the amyloid protein

Amyloid fibrils were extracted from deposits in joint tissue of heavy breed layers with spontaneous amyloid arthropathy and characterized as being of the AA-type. Amino acid sequencing revealed a pattern quite similar to duck AA. Acute phase sera of chicken experimentally injected with Enterococcus faecalis showed a SAA-protein like band cross reacting with anti-chicken AA in immunoblot.

Inhibition of Alzheimer beta-peptide fibril formation by serum amyloid P component

A 39-43-amino acid residue-long fragment (beta-peptide) from the amyloid precursor protein is the predominant component of amyloid deposits in the brain of individuals with Alzheimer's disease. Serum amyloid P component (SAP) is present in all types of amyloid, including that of Alzheimer's disease. We have used an in vitro model to study the effects of purified SAP on the fibril formation of synthetic Alzheimer beta-peptide 1-42. SAP was found to inhibit fibril formation and to increase the solubility of the peptide in a dose-dependent manner. At a 5:1 molar ratio of A beta 1-42 peptide to SAP, fibril formation was completely inhibited, and approximately 80% of the peptide remained in solution even after 4 days of incubation. At lower SAP concentrations, e.g. at peptide to SAP ratio of 1000:1, short fibrillar like structures, lacking amyloid characteristics, were formed. These structures frequently contained associated SAP molecules, suggesting that SAP binds to the polymerizing peptide in a reaction which prevented further fibril formation.

Quantification and mapping of antigenic determinants of serum amyloid A (SAA) protein utilizing sequence-specific immunoglobulins and Eu3+ as a specific probe for time-resolved fluorometric immunoassay

Serum amyloid A (SAA) protein, the most prominent amongst acute-phase proteins, is the specific precursor protein of secondary reactive amyloidosis. The fact that SAA once released into the circulation as a 'free' protein rapidly associates with lipoproteins of the high-density range indicates a specific role in lipoprotein metabolism. In this study a new sensitive assay for quantification of human SAA protein in biological specimens using affinity-purified polyclonal antibodies and Eu3+ as a specific probe for time-resolved fluorometric immunoassay is presented. Both purified SAA and SAA-rich high-density lipoprotein particles served as reliable standards in the indirect and the direct sandwich dissociation-enhanced lanthanide fluorescence immunoassay (DELFIA). The detection limit of the DELFIA technique presented was 4-10 ng after sample dilution of 1/2500. The intra-assay coefficient of variation averaged 4.3% whereas the inter-assay coefficient of variation averaged 6.2%. Comparison with the nephelometric assay, a widely and commonly used assay for SAA quantification in plasma, revealed correlation coefficients of 0.9428. In addition to polyclonal anti-human SAA antibodies sequence-specific antibodies raised against synthetic peptides corresponding to region; 1-17, 14-30, 27-44, 40-63, 59-72, 68-84, 79-94, and 89-104 of the human SAA amino acid sequence were studied. Sequence-specific antibodies raised against epitopes 27-44, 59-72, 68-84, and 89-104 recognize human SAA protein in the DELFIA assay whereas antibodies raised against epitopes 1-17, 14-30, 40-63 and 79-94 failed to recognize the corresponding epitopes. Results obtained from these studies indicate that the N-terminal domain (1-30) as well as epitopes 40-63 and 79-94 of human SAA are apparently masked by the environment of the lipoprotein particle. From our studies it is proposed that the epitopes 31-39, 64-78, and 95-104 may be responsible for the interaction of SAA-rich high density lipoprotein particles with peripheral cells.

Characterization of constitutive human serum amyloid A protein (SAA4) as an apolipoprotein

Serum amyloid A proteins (SAAs), a family of homologous molecules, are apolipoproteins of high density lipoprotein (HDL). They can be divided into two groups. The first group comprises the well-characterized acute phase SAAs that associate with HDL during inflammation, thereby remodeling the HDL particle by displacing apolipoprotein (apo)A-I. The second group consists of the recently discovered constitutive SAAs, mouse SAA5 and human SAA4. They exist as minor apolipoproteins on HDL but constitute more than 90% of the total SAA during homeostasis. We have characterized human SAA4 as an apolipoprotein. During homeostasis, SAA4 is synthesized only in the liver. Purification of SAA4 has been described and its plasma concentration has been established at 55 +/- 13 micrograms/ml in 26 healthy individuals. It was present on all HDL density classes and very low density lipoprotein (VLDL) but was absent from low density lipoprotein (LDL). Using two-dimensional electrophoresis and phosphorimaging, SAA4 was found to be associated with a specific subpopulation of only three HDL particles, not involved in the initial cholesterol transfer from cells.

Human serum amyloid P component binds to a specific peptide in the presence of calcium

Human serum amyloid P component (SAP) binds to a carboxyl-terminal peptide of residues 160-204 of SAP itself in the presence of calcium. A set of sequentially overlapping decapeptides covering the entire length of residues 160-204 of SAP was synthesized on polyethylene pins to be used for binding assay, and six overlapping peptides in residues 190-204 (Tyr-Glu-Ile-Arg-Gly-Tyr-Val-Ile-Ile-Lys-Pro-Leu-Val-Trp-Val) were found to have equally high affinity for SAP. The validity of using peptides on polyethylene pins was shown by the binding assay using 11-residue soluble peptide corresponding to residues 194-204. Replacement of the Lys or the Ile residues with Glu abolished the binding activity.

Serum amyloid protein (SAP) as a marker of autoimmune disease in mice

Acute phase proteins are good markers of inflammatory processes. To clarify whether Serum Amyloid Protein (SAP) can be a marker for the onset of SLE disease in mice, we measured constitutive and inducible SAP levels in normal mice of different strains, in C57Bl/6 lpr/lpr (B6lpr) and [NZB x NZW]F1 (NZB/W) SLE-prone mice, in mice that develop Lupus-like syndrome during chronic Graft versus Host (GvH) reaction and in mice suffering acute GvH reaction. In comparison to B6lpr, NZB/W mice showed higher blood levels of SAP but those levels did not correlate with autoimmune parameters. In B6lpr, the SAP levels steadily increased with age and correlated with some of the parameters used for monitoring the SLE disease. High levels of SAP were also found in mice suffering acute GvH reaction whereas the lupus-like chronic GvH disease was associated with limited increase of SAP levels.

Preparation of anti-canine serum amyloid A (SAA) serum and purification of SAA from canine high-density lipoprotein

Antiserum to canine serum amyloid A (SAA) was prepared in rabbits by immunization with crude SAA which was prepared from high-density lipoprotein 3 (HDL3) obtained from canine acute-phase serum. The antiserum was absorbed for contaminating antibodies by affinity chromatography using Sepharose 4B coupled with normal canine serum proteins. The rabbit anti-canine SAA serum reacted with a protein and formed a single precipitin line at the position of the alpha 1-region of the immunoelectrophoresis of canine acute-phase serum but did not react with the normal canine serum on immunoelectrophoresis. The antibody to canine SAA was also confirmed by Western blotting analysis. Canine SAA was purified as a low molecular weight protein component from crude SAA by preparative sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) after gel filtration chromatography. Purified canine SAA had a molecular weight of 15,000 as estimated by SDS-PAGE. This SAA level was found by enzyme-linked immunosorbent assay (ELISA) to increase 1 day after inoculation with Bordetella bronchiseptica to 9.0-20.1 times the preinoculation value.

The primary structure of serum amyloid A protein in the sheep: comparison with serum amyloid A in other species

Serum amyloid A (SAA) protein was isolated from acute phase sheep sera by ultracentrifugation, gel filtration and ion-exchange chromatography. The purified protein was characterized by sodium dodecylsulfate polyacrylamide gel electrophoresis (SDS-PAGE), isoelectric focusing, amino acid composition and Edman degradation. Protein SAA sheep consists of 112 amino acid residues and has a blocked N-terminus. The amino acid sequence showed a high degree of homology with SAA proteins from other species, especially at positions 32 to 54, indicating that this particular part of the protein is important for its function. When compared to human protein SAA, nine inserted amino acids could be demonstrated, located in regions 69 to 77. Similar observations have been seen in cow, horse, dog, cat, and mink protein SAA. Heterogeneities were found in positions 28, 55, 63, 64, 66, 75, 77, 78, 80 and 89. Positions 63, 64, 66, 75, 77, 78 and 80 revealed the existence of a minor gene product of protein SAA sheep. The minor variant of protein SAA sheep is identical in these positions with the corresponding positions in protein SAA cow. By comparing the amino acid sequences of the different SAA proteins, two separate branches in the evolutionary pattern of protein SAA appear. One of the branches includes the species with the insertion which represents also one of the more heterogeneous part of the protein.

Purification and quantitative measurement of bovine serum amyloid-A

Bovine serum amyloid-A (b-SAA) was purified from a pool of acute phase serum using hydrophobic interaction chromatography and gel filtration. Serum was applied at a low salt concentration to a phenyl-sepharose column and SAA was eluted with a gradient of 0 to 6 M guanidine-HCl. Fractions containing SAA were pooled, concentrated and further purified by gel filtration on Superose-12. The concentration of SAA in bovine serum was quantified by an indirect ELISA using rabbit anti-human SAA and horseradish peroxidase conjugated donkey anti-rabbit IgG. Dilutions of an acute phase bovine serum sample were used as working standards. The SAA concentration of this standard was determined by comparison with purified b-SAA on SDS-polyacrylamide gel electrophoresis followed by densitometry at 590 nm. The assay detection limit was 3 micrograms ml-1; the intra-assay coefficient of variation was 4 per cent and interassay coefficients of variation were 5.5 per cent and 7.2 per cent at 66 and 178 micrograms ml-1 SAA, respectively. In calves experimentally infected with Pasteurella haemolytica type A1 the ELISA was able to detect a 10-fold increase of SAA within 24 hours of inoculation.

Recombinant murine serum amyloid A from baculovirus-infected insect cells: purification and characterization

Serum amyloid A (SAA) is an extremely sensitive acute-phase reactant and precursor to the subunit protein in reactive amyloid deposits. Although the mouse has long served as an informative experimental model, both the function of SAA and the pathogenic mechanism of amyloid formation remain unknown. The production of SAA by a heterologous system was pursued as means of generating readily-renewable amounts of SAA of defined sequence. Murine SAA2 has been expressed in and purified from baculovirus-infected insect cells. Using the transfer vector pBlueBac, SAA2 cDNA was cloned into baculovirus DNA such that expression was under the control of the polyhedrin promoter. Lysates prepared from infected cells contained three amyloid A-immunoreactive forms which accumulated intracellularly over a three day periods. The form having the lowest relative molecular mass, 12.5 kDa, co-migrated in SDS-polyacrylamide gels with the SAA2 present in murine acute-phase serum. Recombinant SAA2 was purified by Sepharose CL-6B chromatography followed by chromatofocusing between pH 8 and pH 5. Amino-terminal sequencing of the purified 12.5 kDa sample confirmed the first 20 residues of mature murine SAA2. After incubation with normal mouse serum, purified recombinant SAA2 fractionated exclusively with lipoprotein complexes, suggesting that it was bound to HDL. Based on this observation, we believe that recombinant SAA can serve as a suitable substitute for the native protein in physiologically relevant studies.

The primary structure of rabbit serum amyloid A protein isolated from acute phase serum

Serum amyloid A (SAA) protein, a sensitive acute phase protein and the precursor of protein AA in secondary amyloid, was purified from pooled acute phase rabbit serum using two different methods: isolation of protein SAA directly by octyl-Sepharose chromatography of total serum, and dissociation and isolation of apoSAA from acute phase high density lipoprotein (HDL). The protein SAA fraction obtained was further purified using gel filtration and ion exchange chromatography. Rabbit protein SAA has 104 amino acid residues, like human SAA, and has a partially blocked N terminus. The highly conserved region from position 33 to position 63 found in SAA from all species studied was confirmed also in rabbit SAA. No microheterogeneities were observed. The amino acid sequence showed extensive N-terminal homology with the rabbit amyloid A protein, except for the microheterogeneity in position 12 in protein AA. It also showed identical amino acid sequence with that deduced from the rabbit cDNA clone pSAA 55. Complete homologies were found with clone SAA 2, except for positions 22 and 78, clone SA8-1, except for positions 22 and 79 and clone SA7-3, except for position 22. This pSAA 55/SA7-3/SA8-1/SAA2-like protein was the only SAA isotype found both in total serum and in the HDL fraction. Isotypes corresponding to other SAA-like genes could not be found in this pool of acute phase rabbit sera.

[Amyloidosis as cause of severe abdominal symptoms in a young Somali immigrant?]

Extensive deposition of amyloid was detected in the digestive tract of a Somali woman aged 20 yr with abdominal pain, diarrhoea and cachexia. Immunohistochemical characterisation showed that the amyloid protein involved was of the AA type. Elevated levels were also found for serum amyloid A (SAA), an acute-phase protein which is the precursor of AA amyloid. The underlying inflammatory disease was peritoneal tuberculosis. The normalisation of the SAA levels and the recovery of the small intestine during tuberculostatic therapy showed that the tuberculosis was the cause of the enteropathy. This case report highlights the importance of early detection and effective treatment of the underlying inflammatory disease in case of AA amyloidosis.

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 SAA2 alpha and the other corresponded to positions 2-76 (or 75) of known SAA1 subsets, except for position 52 or 57, where SAA1 alpha has valine and alanine and SAA1 beta 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., SAA152,57Ala.

Purification of serum amyloid A and its isoforms from human plasma by hydrophobic interaction chromatography and preparative isoelectric focusing

The present work was aimed at isolating human serum amyloid A, (SAA), an acute-phase protein mainly complexed to high density lipoproteins, directly from human plasma without sequential ultracentrifugation of lipoproteins and subsequent delipidation of the apolipoprotein moiety. Hydrophobic-interaction fast-protein liquid chromatography on Octylsepharose, using stepwise gradient elution profiles under dissociating conditions, followed by fast-protein liquid-gel permeation chromatography on a Superdex TM75 column revealed a higher than 95% purity of isolated SAA. Further purification of SAA from coeluting apolipoproteins C and A-II was achieved by preparative isoelectric focusing between pH5-7 using a Rotofor apparatus. Separation of the main SAA isoforms, SAA1 (pI 6.5) and SAA1 des-Arg (pI 6.0, lacking the N-terminal arginine), was achieved by anion-exchange fast-protein liquid chromatography on a Fractogel EMD DEAE 650-S column. The purity of the SAA1 and SAA1 des-Arg isoforms, thus isolated, was checked by immunochemical techniques and amino acid analysis. With the described method various SAA isoforms can be isolated, purified and separated directly from human plasma/serum without prior ultracentrifugation.

The complete amino acid sequence of bovine serum amyloid protein A (SAA) and of subspecies of the tissue-deposited amyloid fibril protein A

Bovine serum amyloid A (SAA) was isolated from the acute phase high density lipoprotein (HDL) fraction of a cow suffering from acute mastitis. The elucidated primary structure revealed a protein consisting of 112 amino acid residues. Compared with SAA proteins from other species, the bovine protein was shown to have an insertion of nine amino acid residues between positions 69 and 70. No microheterogeneity could be observed in the protein. Amyloid fibrils extracted from the kidneys were found to contain at least three subspecies of protein AA, consisting of 68, 81 and about 110 amino acid residues. The amino acid sequences established for the protein AA subspecies revealed no microheterogeneity, and were identical to that elucidated for protein SAA.

Isolation and purification of amyloid protein A by sodium dodecyl sulphate polyacrylamide gel electrophoresis and reversed-phase high-performance liquid chromatography

Sodium dodecyl sulphate polyacrylamide gel electrophoresis and reversed-phase high-performance liquid chromatography (HPLC) were used consecutively for the isolation of amyloid protein A (protein AA) from amyloid fibrils. Highly purified protein AA was obtained and determined by electrophoretic and amino acid analyses. The heterogeneity of protein AA was shown by HPLC. The isoforms of protein AA had different hydrophobicities, although they were equal in size and similar in amino acid composition. Compared with the conventional amyloid separation procedure (gel permeation chromatography), this technique is rapid, requires only small amounts of amyloid fibrils and may provide new information on amyloid proteins.

Amino acid sequence analyses of non-AA proteins from amyloid fibrils of bovine kidney

The elution pattern obtained when amyloid fibrils from amyloid-laden bovine kidneys were subjected to gel filtration under dissociating conditions revealed a larger amount of non-AA material (eluting between the void volume and protein AA) than usually seen in other species. SDS-PAGE of this non-AA fraction yielded several Coomassie blue stained bands. The most distinctive ones gave estimated molecular masses of 15 kDa, 18 kDa, 33 kDa and 43 kDa. These molecular species were electroblotted onto PVDF membranes, and were further characterized by amino acid composition analyses, cyanogen bromide cleavage and N-terminal analyses. The results revealed that the intermediate 'non-AA' fraction consisted of histones H2B, H3 and H4 in addition to protein AA also found in this fraction.

Characterization of an isoelectric focusing variant of SAA1 (ASP-72) in a family of Turkish origin

An acidic variant of serum amyloid A (SAA) identified previously by isoelectrofocusing in a family of Turkish origin has been characterized at the genomic level. DNA sequence analysis revealed that individuals expressing the variant pI6.1/pI5.7 isoforms (the mother and three of four children) were heterozygous at the SAA1 gene locus. Their SAA1 gene sequences contained an adenine, as well as the usual guanine, at the position corresponding to the second base of codon 72. The presence of both bases predicts two SAA1 protein sequences, one having aspartic acid and the other glycine at position 72. While the Gly-72 SAA1 (+/- Arg-1) sequence represents the normal pI6.5/pI6.0 isoforms, the Asp-72 SAA1 (+/- Arg-1) sequence corresponds to the variant pI6.1/pI5.7 isoforms.

Characterization of proteoglycans and glycosaminoglycans in bovine renal AA-type amyloidosis

Highly sulfated glycosaminoglycans (GAG) or proteoglycans (PG), especially heparan sulfate (HS) and heparan sulfate proteoglycan (HSPG), are considered to be intimately associated with amyloid deposits in different types of amyloidosis. Based on this relationship an important role for HS has been suggested in amyloidogenesis. The present immunohistological and ultrastructural study shows that in bovine renal AA-amyloidosis, sulfated GAG/PG was not restricted to amyloid deposits proper and that areas without GAP/PG were also present within the amyloid. Both glomerular and papillary amyloid contained HS (PG), and the latter also contained chondroitin sulfate (CS) and dermatan sulfate (DS), suggesting a correlation between the location of the amyloid and the type of GAG/PG deposited. Amyloid P component (AP) had a distribution similar to that of HSPG, confirming their affinity-based relationship. The GAG types found ultrastructurally in amyloid fibril preparations of glomerular and papillary amyloid isolated from the same kidney, reflected the immunohistological findings. HS was shown to be the predominant GAG in all papillary amyloid fibril extracts. Taking into account the chemico-physical properties of HS, it cannot be excluded that this predominance is introduced by the purification procedure. These results suggest that the association of GAG/PG and amyloid is not necessarily mutually obligatory and that the proposed importance of GAG in amyloidogenesis is disputable.

Serum amyloid A isoforms in inflammation

Serum amyloid A protein (SAA) was extracted from serum using hydrophobic interaction chromatography and four or six isoforms were separated by isoelectric-focusing. These represented three pairs of isoforms, each with and without an N-terminal arginine. SAA1 (pI 6.1), SAA1 des-arg (pI 5.9), SAA2 alpha (pI 6.9) and SAA2 alpha des-arg (pI 6.6) were found to be present in all individuals from Europe and the USA. A minority of these individuals (11 of 56) expressed SAA2 beta (pI 7.1) and SAA2 beta des-arg (pI 6.8). Serum from patients in Papua New Guinea and Malawi both showed a much higher frequency of SAA2 beta. There was no indication of altered isoforms in regions with high incidence of reactive AA amyloidosis. In sequential serum samples, concentrations of des-arg isoforms were found to reach a maximum 0-24 h later than isoforms with an arginine. Concentrations of the isoform SAA1 decreased faster in five of six patients (16 +/- 7.5 h to decrease 50%) than SAA1 des-arg (22 +/- 11 h to decrease 50%). Variations in the handling of N-terminal arginine may be important for the formation-susceptibility of amyloid deposits.

Inhibition of the oxidative burst response of N-formyl peptide-stimulated neutrophils by serum amyloid-A protein

Strong binding of the acute phase protein serum amyloid-A (SAA) to human neutrophils was found using flow cytometry. This binding was shown to be functionally relevant with respect to the oxidative burst reaction assayed on N-formyl peptide-stimulated neutrophils by the intracellular oxidation of non-fluorescent dihydrorhodamine to fluorescent rhodamine 123. The results show reduction of the oxidative burst response by isolated SAA (and recombinant SAA2). Inhibition was also demonstrated by acute phase as compared to normal human serum. This inhibitory effect was abolished by the purified monoclonal anti-amyloid A antibody mc29, strongly suggesting that SAA counteracts neutrophil responses to cytokines or bacterial products. This newly recognized function of SAA may help to prevent oxidative tissue destruction.

Use of ethanol-eluted hydrophobic interaction chromatography in the purification of serum amyloid A

A two-step procedure for the purification of the acute-phase reactant serum amyloid A from serum is described. A hydrophobic interaction chromatography medium, octyl-Sepharose CL4B, eluted with increasing concentrations of EtOH was used as the first step in the purification. The concentrate from this step was applied to a gel filtration column of Sephacryl S-200 and eluted with 10% formic acid. The overall recovery of purified serum amyloid A from serum was 56%. This represents the first time that serum amyloid A has been purified without the use of high concentrations of guanidine or urea. The method presented could easily be scaled up to allow the purification of large quantities of serum amyloid A or readily adapted to the purification of other serum apolipoproteins.

Identification of glycosaminoglycans in human renal and splenic secondary AA amyloid fibril preparations

The evidence that glycosaminoglycans (GAGs) are specifically associated with amyloid, is strong. In the present study we looked for GAGs in water extracts of amyloid fibrils from kidney and spleen laden with AA amyloid secondary to ankylosing spondylitis. Significant amounts of high molecular weight GAGs were isolated from the fibril preparations of both organs using ion-exchange chromatography and gel filtration procedures. The polysaccharides present in purified human renal and splenic amyloid fibril material were characterized as follows: a) Sulphated GAGs of high molecular weight were found in both renal and splenic amyloid fibril extracts, but not in extracts from corresponding normal tissues. b) All of the renal amyloid-associated high molecular weight GAGs were chondroitin sulphate/dermatan sulphate, whereas splenic amyloid-associated high molecular weight GAGs had a chondroitin sulphate/dermatan sulphate:heparan sulphate ratio of approximately 2:1. c) The findings gave no evidence that GAGs coisolated with AA amyloid fibrils were parts of intact proteoglycan molecules with several GAG chains.

AA-amyloidosis. Tissue component-specific association of various protein AA subspecies and evidence of a fourth SAA gene product

Protein AA, the major repetitive protein subunit present in fibrils deposited in AA-amyloidosis, is an N-terminal cleavage product of a 104-amino acid precursor, serum amyloid A (SAA). Protein AA subspecies varying between 45 and 94 amino acids in length have been described. In this study it is shown that the different protein AA subspecies are not evenly distributed in amyloid deposits and that in single patients, certain subspecies of protein AA are deposited in specific tissue component sites. Thus larger protein AA subspecies occur in lower concentration in amyloid in the glomeruli compared to other sites and are especially found in amyloid in vessel walls. Three different SAA forms have been predicted from genomic and complementary DNA studies. The existence of a fourth type has been suspected from amino acid sequence studies of purified SAA. Protein AA derived from this fourth type of SAA is now shown to be present in amyloid fibrils in one of the patients studied in this paper.

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.

Purification and characterization of hamster serum amyloid A protein (SAA) by cholesteryl hemisuccinate affinity chromatography

High-density lipoprotein (HDL) apolipoprotein was separated from hamster serum by cholesteryl hemisuccinate affinity chromatography (CHAC) in comparison with the density-gradient ultracentrifugation (DGUC). The apolipoprotein recovery from serum by CHAC was 70% and by DGUC 80%. This disadvantage is compensated for by the ease of purification by CHAC, a method particularly suited for the processing of large amounts of serum. From the acute-phase HDL CHAC fraction, apo SAA was isolated by gel filtration. Using isoelectrofocusing, two-dimensional gel electrophoresis, and titration curve, four isotypes of hamster apo SAA were identified and characterized. In the acute-phase serum, one of the isotypes was predominant (apo SAA1). In serum of amyloidotic animals, the relative contribution of apo SAA1 was considerably lower, suggesting selective removal of the latter during amyloidogenesis and possibly its deposition in hamster AA amyloid. Furthermore, the affinity chromatography method was modified with gradient elution of affinity-bound material. By this method HDL apolipoprotein was separated into three subclasses. Apo SAA was shown to associate with two different subclasses. In acute-phase serum most of the apo SAA1 was found in the subclass with the lowest affinity for the cholesteryl beads, whereas the latter was depressed in amyloidotic serum, suggesting that the amyloidogenicity of a particular apo SAA isotype is determined by its cholesteryl-binding properties.