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

Time course of gene expression profiling in the liver of experimental mice infected with Echinococcus multilocularis

BACKGROUND

Alveolar echinococcosis (AE) is a severe chronic parasitic disease which behaves like a slow-growing liver cancer. Clinical observations suggest that the parasite, Echinococcus multilocularis (E. multilocularis) influences liver homeostasis and hepatic cell metabolism. However, this has never been analyzed during the time course of infection in the common model of secondary echinococcosis in experimental mice.

METHODOLOGY/PRINCIPAL FINDINGS

Gene expression profiles were assessed using DNA microarray analysis, 1, 2, 3 and 6 months after injection of E. multilocularis metacestode in the liver of susceptible mice. Data were collected at different time points to monitor the dynamic behavior of gene expression. 557 differentially expressed genes were identified at one or more time points, including 351 up-regulated and 228 down-regulated genes. Time-course analysis indicated, at the initial stage of E. multilocularis infection (month 1-2), that most of up-regulated pathways were related to immune processes and cell trafficking such as chemokine-, mitogen-activated protein kinase (MAPK) signaling, and down-regulated pathways were related to xenobiotic metabolism; at the middle stage (month 3), MAPK signaling pathway was maintained and peroxisome proliferator-activated receptor (PPAR) signaling pathway emerged; at the late stage (month 6), most of up-regulated pathways were related to PPAR signaling pathway, complement and coagulation cascades, while down-regulated pathways were related to metabolism of xenobiotics by cytochrome P450. Quantitative RT-PCR analysis of a random selection of 19 genes confirmed the reliability of the microarray data. Immunohistochemistry analysis showed that proliferating cell nuclear antigen (PCNA) was increased in the liver of E. multilocularis infected mice from 2 months to 6 months.

CONCLUSIONS

E. multilocularis metacestode definitely exerts a deep influence on liver homeostasis, by modifying a number of gene expression and metabolic pathways. It especially promotes hepatic cell proliferation, as evidenced by the increased PCNA constantly found in all the experimental time-points we studied and by an increased gene expression of key metabolic pathways.

The in-vitro influence of serum amyloid A isoforms on enzymes that regulate the balance between esterified and un-esterified cholesterol

The intracellular balance between un-esterified and esterified cholesterol is regulated by two enzyme activities, cholesterol ester hydrolases, which drive the balance in favor of un-esterified cholesterol, and acyl-CoA:cholesterol acyl transferase (ACAT) which acts in the opposite direction. During acute inflammation apo-serum amyloid A (apoSAA) isoforms 1.1 and 2.1 become major constituents of high density lipoprotein and this complex is internalized by macrophages. Mixtures of the two isoforms have been shown to enhance cholesterol esterase activity. Using a purified form of the pancreatic enzyme we have explored the mechanism by which apoSAA may accomplish this stimulation. The pancreatic esterase cleaves cholesteryl-oleate with a Km of 0.255 mM, releasing both cholesterol and oleate. Cholesterol exhibits a product inhibition which is relieved by isoform 2.1 but not 1.1 nor apolipoprotein A-I. The NH2-terminal 16 residues of isoform 2.1 had no effect on the esterase, but the 80 residue peptide constituting its COOH-terminus possessed the stimulatory property. Purified isoforms 1.1, 2.1, 2.2, apolipoprotein A-I, the NH2-terminal 16 residues and COOH-terminal 80 residues of isoform 2.1 were also examined for their effects on macrophage ACAT activity. Isoforms 2.1 and 2.2 produced dose dependent inhibitions of up to 50%, (p<0.001). Isoform 1.1, and apoA-I had no effect on ACAT activity. The NH2-terminal 16 residue peptide of isoform 2.1 reduced the ACAT activity in a dose dependent manner by 74% (p<0.001), whereas the COOH-terminal 80 residues, in contrast to its enhancing effect on the esterase, had no inhibitory effect on ACAT. Such complementary but opposite effects of isoform 2.1 on ACAT and the esterase are consistent with a role for this protein in shifting the balance between unesterified (transportable) and esterified (storage) forms of cholesterol in favor of the latter. They suggest that apoSAA2.1 may mediate cholesterol mobilization at sites of tissue injury.

Serum amyloid A, the major vertebrate acute-phase reactant

The serum amyloid A (SAA) family comprises a number of differentially expressed apolipoproteins, acute-phase SAAs (A-SAAs) and constitutive SAAs (C-SAAs). A-SAAs are major acute-phase reactants, the in vivo concentrations of which increase by as much as 1000-fold during inflammation. A-SAA mRNAs or proteins have been identified in all vertebrates investigated to date and are highly conserved. In contrast, C-SAAs are induced minimally, if at all, during the acute-phase response and have only been found in human and mouse. Although the liver is the primary site of synthesis of both A-SAA and C-SAA, extrahepatic production has been reported for most family members in most of the mammalian species studied. In vitro, the dramatic induction of A-SAA mRNA in response to pro-inflammatory stimuli is due largely to the synergistic effects of cytokine signaling pathways, principally those of the interleukin-1 and interleukin-6 type cytokines. This induction can be enhanced by glucocorticoids. Studies of the A-SAA promoters in several mammalian species have identified a range of transcription factors that are variously involved in defining both cytokine responsiveness and cell specificity. These include NF-kappaB, C/EBP, YY1, AP-2, SAF and Sp1. A-SAA is also post-transcriptionally regulated. Although the precise role of A-SAA in host defense during inflammation has not been defined, many potential clinically important functions have been proposed for individual SAA family members. These include involvement in lipid metabolism/transport, induction of extracellular-matrix-degrading enzymes, and chemotactic recruitment of inflammatory cells to sites of inflammation. A-SAA is potentially involved in the pathogenesis of several chronic inflammatory diseases: it is the precursor of the amyloid A protein deposited in amyloid A amyloidosis, and it has also been implicated in the pathogenesis of atheroscelerosis and rheumatoid arthritis.

Fourier transform infrared spectroscopic investigation of temperature- and pressure-induced disaggregation of amyloid A

The conformation-sensitive amide I band in the Fourier transform infrared (FTIR) spectra of amyloid A suspensions in D2O was examined as a function of temperature (25-95 degrees C) and applied hydrostatic pressure (1-12 kbar) to assess the stability of the peptide. The principal changes observed upon heating were a significant loss of intermolecular beta-sheet structure, and an increase in the broad band centred at 1644 cm(-1) assigned to unordered structure and alpha-helices of the dissociated species. Application of hydrostatic pressure at ambient temperature resulted in a limited degree of aggregate dissociation. These structural changes were partially reversible with cooling or release of the applied pressure. Dissolving the aggregated peptide in alkaline solution (pH 12) also resulted in disaggregation. Dissociation of organ-deposited amyloid substance bears clinical relevance. The present data indicate that residual amounts of undissociated amyloid in the milieu at physiological and acidic pH may act as nucleating foci rendering dissociated amyloid to reaggregate into organized amyloid.

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.

Bruton's tyrosine kinase expression and activity in X-linked agammaglobulinaemia (XLA): the use of protein analysis as a diagnostic indicator of XLA

Mutations in the Bruton's tyrosine kinase (BTK) gene result in XLA. Despite the large numbers of BTK mutations reported, no correlation can be made between the clinical phenotype and the gene defects. Analysis of Btk protein expression and activity in individuals with XLA was performed to characterize the relationship between a particular mutation, the resultant Btk protein and the clinical phenotype. In most patients studied, including those with atypical phenotypes, there was complete absence of protein expression and activity. Furthermore, in two undiagnosed individuals with a clinical phenotype suggestive of XLA, lack of protein expression was used to confirm an abnormality in Btk. These results underline the importance of protein analysis prior to speculating on protein structure and function based on the gene mutation. Lack of Btk expression in atypical phenotypes suggests that there is redundancy in B lymphocyte signalling such that alternative signalling molecules, or mechanisms, can compensate for the lack of Btk. We also suggest that analysis of Btk expression can be used as an indicator of XLA. These rapid assays may be used to screen a wider spectrum of individuals with humoral immunodeficiency in order to characterize fully the extent of Btk deficiency.