Biosynthesis of human acute-phase serum amyloid A protein (A-SAA) in vitro: the roles of mRNA accumulation, poly(A) tail shortening and translational efficiency.

Human 'acute-phase' serum amyloid A protein (A-SAA) is a major acute-phase reactant (APR) and an apolipoprotein of high density lipoprotein 3 (HDL3). We have examined several parameters of A-SAA biosynthesis in PLC/PRF/5 hepatoma cells in response to monocyte conditioned medium (MoCM) and dual treatment with interleukin-1 beta and interleukin-6 (IL-1 beta + IL-6). Treatment of PLC/PRF/5 cells with MoCM or IL-1 beta + IL-6 caused a dramatic and rapid increase in A-SAA mRNA and protein synthesis; A-SAA mRNA was first detectable at 3 h, with peak levels reached by 24 h. A-SAA mRNA accumulation is accompanied by a gradual and homogeneous decrease in the length of the A-SAA poly(A) tail; the poly(A) tail shortening does not apparently affect the intrinsic stability of A-SAA mRNA. Analysis of RNA isolated from the ribonucleoprotein, monosome and polysome fractions of cytokine-treated PLC/PRF/5 cells showed that most A-SAA mRNA was associated with small polyribosomes, regardless of time post-stimulus, suggesting that the translational efficiency of A-SAA mRNA is constant throughout cytokine-driven induction. Moreover, the transit time of A-SAA protein out of the cell is also constant throughout the time course of induction. These data provide evidence of a paradox with regard to the transcriptional upregulation of A-SAA by IL-1 beta + IL-6 and the relative synthesis of A-SAA protein and suggest a role for post-transcriptional control of A-SAA biosynthesis during the acute phase.

Dog serum amyloid A protein. Identification of multiple isoforms defined by cDNA and protein analyses.

Five distinct serum amyloid A (SAA) cDNA clones have been isolated from a library constructed using hepatic mRNA isolated from an individual beagle dog with canine pain syndrome. This implies the existence of at least three SAA genes in the dog genome. One clone predicts a truncated "amyloid A-like" SAA molecule and offers a possible alternative mechanism for the pathogenesis of secondary amyloidosis. Relative to the human and mouse SAA proteins, an additional peptide of eight amino acids is specified by each of the dog cDNA clones. The existence of this peptide in all acute phase dog SAA proteins was confirmed by polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate of acute phase high density lipoprotein and provides supporting evidence for gene conversion as a mechanism for maintaining the homogeneity of the SAA gene family within a species. Analysis of hepatic RNA following induction of an acute phase response shows a dramatic increase in SAA mRNA concentration; the SAA transcripts show a transient increase in size early in inflammation due to an increase in polyadenylation.

Major acute-phase reactant synthesis during chronic inflammation in amyloid-susceptible and -resistant mouse strains.

Hepatic levels of mRNA specific for total serum amyloid A (SAA), the SAA1 and SAA2 isotypes, serum amyloid P (SAP), C-reactive protein (CRP), and fibronectin, as well as the plasma concentrations of SAA and SAP were examined in amyloid-resistant (A/J) and amyloid-susceptible (CBA/J) mice during azocasein-induced chronic inflammation. In both strains hepatic SAA and SAP mRNA levels and plasma SAA and SAP protein concentrations increased dramatically during the early stages of inflammation; this was followed by a decrease to concentrations that were maintained at levels considerably higher than background. The ratios of SAA1 and SAA2 mRNA and plasma protein were 1:1 throughout. This indicated that there was no preferential accumulation of mRNA specifying a particular isotype and no preferential synthesis or clearance of a particular isotype during chronic inflammation and the early stages of amyloidogenesis in either strain. Similarly, hepatic SAP mRNA levels in both strains increased dramatically during the early stages of inflammation and were subsequently maintained at elevated levels. Plasma SAP concentrations increased rapidly during the first three days of the study in both A/J and CBA/J mice; however, during the later stages of inflammation, A/J plasma SAP levels decreased to a steady-state concentration that was approximately half that observed in CBA/J mice. Our results identify differences in the hepatic mRNA and plasma protein levels of the major mouse acute-phase reactants (APR) in the amyloid-resistant A/J and amyloid-susceptible CBA/J mouse strains. These findings are consistent with circulating inflammatory APR concentrations contributing, together with other factors, to the onset and pathogenesis of secondary amyloidosis.