Activation of SIRT1 by resveratrol represses transcription of the gene for the cytosolic form of phosphoenolpyruvate carboxykinase (GTP) by deacetylating hepatic nuclear factor 4alpha.

The SIRT1 activators isonicotinamide (IsoNAM), resveratrol, fisetin, and butein repressed transcription of the gene for the cytosolic form of phosphoenolpyruvate carboxykinase (GTP) (PEPCK-C). An evolutionarily conserved binding site for hepatic nuclear factor (HNF) 4alpha (-272/-252) was identified, which was required for transcriptional repression of the PEPCK-C gene promoter caused by these compounds. This site contains an overlapping AP-1 binding site and is adjacent to the C/EBP binding element (-248/-234); the latter is necessary for hepatic transcription of PEPCK-C. AP-1 competed with HNF4alpha for binding to this site and also decreased HNF4alpha stimulation of transcription from the PEPCK-C gene promoter. Chromatin immunoprecipitation experiments demonstrated that HNF4alpha and AP-1, but not C/EBPbeta, reciprocally bound to this site prior to and after treating HepG2 cells with IsoNAM. IsoNAM treatment resulted in deacetylation of HNF4alpha, which decreased its binding affinity to the PEPCK-C gene promoter. In HNF4alpha-null Chinese hamster ovary cells, IsoNAM and resveratrol failed to repress transcription from the PEPCK-C gene promoter; overexpression of HNF4alpha in Chinese hamster ovary cells re-established transcriptional inhibition. Exogenous SIRT1 expression repressed transcription, whereas knockdown of SIRT1 by RNA interference reversed this effect. IsoNAM decreased the level of mRNA for PEPCK-C but had no effect on mRNA for glucose-6-phosphatase in AML12 mouse hepatocytes. We conclude that SIRT1 activation inhibited transcription of the gene for PEPCK-C in part by deacetylation of HNF4alpha. However, SIRT1 deacetylation of other key regulatory proteins that control PEPCK-C gene transcription also likely contributed to the inhibitory effect.

Binding of C/EBPbeta to the C-reactive protein (CRP) promoter in Hep3B cells is associated with transcription of CRP mRNA.

Expression of the acute phase protein C-reactive protein (CRP) is tightly regulated in hepatocytes. Although very little CRP mRNA is transcribed normally, inflammatory stimuli are followed by a dramatic increase in mRNA synthesis and accumulation. IL-6 and IL-1beta are believed to be the major cytokines responsible for induction of CRP and other acute phase proteins. Our previous studies, using transient transfection and EMSA experiments, implicated involvement of the transcription factors C/EBPbeta, STAT3, Rel p50, and c-Rel in CRP induction. In the current study we used chromatin immunoprecipitation assays to determine the kinetics of transcription factor occupancy of these transcription factors on the endogenous CRP promoter. All of these transcription factors were found bound to the endogenous CRP promoter in the absence of cytokines, but cytokine treatment markedly increased binding of only C/EBPbeta. In addition, c-Rel and TATA box-binding protein (TBP) appeared to occupy the promoter in parallel in the presence of cytokines. In the absence of cytokines, CRP mRNA accumulation was not measurable but began to increase by 3 h after exposure of cells to IL-1beta plus IL-6, peaking at 12 h with secondary peaks at 18 and 24 h. The secondary peaks in mRNA expression paralleled the pattern of binding of c-Rel and TBP to the CRP promoter. We conclude that the CRP promoter has a low level of transcription factor occupancy in the absence of cytokines and induction occurs with binding of C/EBP, and that c-Rel and TBP are important for modulating CRP expression.

Adiponectin decreases C-reactive protein synthesis and secretion from endothelial cells: evidence for an adipose tissue-vascular loop.

BACKGROUND AND OBJECTIVE: Inflammation is pivotal in atherosclerosis. C-reactive protein (CRP), in addition to being a cardiovascular risk marker, may also be proatherogenic. We have previously shown that in addition to the liver, human aortic endothelial cells (HAECs) synthesize and secrete CRP. Whereas CRP levels are increased in obesity, metabolic syndrome, and diabetes, levels of adiponectin are reduced in these conditions. We tested the hypothesis that adiponectin reduces CRP synthesis and secretion in HAECs under normoglycemic (5.5 mmol/L glucose) and hyperglycemic conditions (15 mmol/L glucose). METHODS AND RESULTS: Adiponectin dose-dependently reduced CRP mRNA and protein from HAECs. Adiponectin treatment of HAECs significantly decreased IkappaB phosphorylation and NFkappaB binding activity. There was no effect of adiponectin on STAT or C/EBP transcriptional activity. Adiponectin also activated AMP kinase resulting in decreased NFkappaB activity and decreased CRP mRNA and protein. These effects of adiponectin were mimicked by AICAR, an activator of AMPK, and reversed by inhibition of AMPK. Thus, adiponectin reduces CRP synthesis and secretion from HAECs under hyperglycemia via upregulation of AMP kinase and downregulation of NFkappaB. Similar findings were observed in rat primary hepatocytes. CONCLUSIONS: Thus, in obesity and diabetes, the hypoadiponectinemia could exacerbate the proinflammatory state by inducing CRP production.

C-reactive protein downregulates endothelial NO synthase and attenuates reendothelialization in vivo in mice.

C-reactive protein (CRP) is an acute-phase reactant that is positively associated with cardiovascular disease risk and endothelial dysfunction. In cell culture, CRP decreases the expression of endothelial NO synthase (eNOS), which regulates diverse endothelial cell (EC) functions including migration. To determine whether CRP alters EC gene expression and phenotype in vivo, we studied CF1 transgenic mice expressing rabbit CRP (CF1-CRP) regulated by the phosphoenolpyruvate carboxykinase promoter such that levels could be altered by changing carbohydrate intake. Compared with CF1 controls with CRP of <1 microg/mL, carotid artery reendothelialization after perivascular electric injury was blunted in CF1-CRP mice, with CRP levels as low as 9 microg/mL. eNOS mRNA and enzyme abundance in carotid arteries was also blunted by CRP at 9 microg/mL in vivo, and ex vivo studies of isolated arteries showed that this occurs via direct action on the endothelium. The impaired reendothelialization with CRP was mimicked by NOS antagonism in CF1 mice; conversely, in cultured ECs CRP attenuation of migration was prevented by exogenous NO. Studies of EC transfected with human eNOS 5' flanking sequence fused to luciferase indicated that CRP decreases eNOS gene transcription. Both mutagenesis and electrophoretic mobility shift assays further revealed that CRP-responsive elements reside within the first 79 bp of the eNOS promoter. Thus, CRP downregulates eNOS and attenuates reendothelialization in vivo in mice, and this action of CRP on eNOS is mediated at the level of gene transcription.

The interaction of C-Rel with C/EBPbeta enhances C/EBPbeta binding to the C-reactive protein gene promoter.

C-reactive protein (CRP) is a plasma protein primarily synthesized in the liver following inflammatory stimuli as part of the acute phase response. Expression of CRP is tightly regulated in hepatocytes. Normally very little CRP mRNA is transcribed, but inflammatory stimuli are followed by a dramatic increase in mRNA synthesis and accumulation. Interleukins -6 and 1 (IL-6 and IL-1) are believed to be the major cytokines responsible for induction of acute phase protein biosynthesis. We previously demonstrated that in vivo c-Rel plays a novel regulatory role in that it appears to be in complex with C/EBPbeta when C/EBPbeta is bound to the CRP gene promoter following cytokine stimulation, but is not itself bound to DNA. In this study we found that recombinant c-Rel((1-300)) (truncated c-Rel protein missing the transactivation domain) increased the affinity of recombinant C/EBPbeta for a CRP-derived C/EBP site (-53) at least 10-fold. This effect was independent of a previously described p50 binding site at -43 and of binding of c-Rel to DNA. C/EBPbeta and c-Rel((1-300)) were found to physically interact in solution, and overexpression of c-Rel (either full length or truncated (1-300)) in the presence of overexpressed C/EBPbeta stimulated CRP transcription. We conclude that c-Rel((1-300)) binding to C/EBPbeta increases the affinity of C/EBPbeta for the C/EBP binding site at -53 on the CRP promoter, and that the transactivation domain of c-Rel is not necessary for this effect, which depends on protein: protein contacts with C/EBPbeta.

C-reactive protein causes downregulation of vascular angiotensin subtype 2 receptors and systolic hypertension in mice.

BACKGROUND: Chronic elevations in circulating C-reactive protein (CRP) are associated with a greater risk of hypertension. Whether elevations in CRP cause hypertension is unknown. METHODS AND RESULTS: Chronic, conscious blood pressure (BP) measurements were performed by radiotelemetry in wild-type CF1 control and CF1 transgenic mice expressing rabbit CRP (CF1-CRP) under the regulation of the phosphoenolpyruvate carboxykinase promoter. Compared with controls, CF1-CRP mice had hypertension that was predominantly systolic, and the severity of hypertension varied in parallel with changes in CRP levels modulated by dietary manipulation. Mice that were hemizygous for the transgene with CRP levels of 9 microg/mL were also hypertensive, indicating that modest elevations in CRP are sufficient to alter BP. CRP transgenic mice had exaggerated BP elevation in response to angiotensin II and a reduction in vascular angiotensin receptor subtype 2 (AT2) expression. In contrast, the decline in BP with angiotensin receptor subtype 1 (AT1) antagonism and vascular AT1 abundance were unaltered, which indicates a selective effect of CRP on AT2. Ex vivo experiments further showed that the CRP-induced decrease in AT2 is a direct effect on the vascular wall, not requiring systemic responses, and that it is reversed by an NO donor, which indicates a role for NO deficiency in the process. In parallel, the chronic inhibition of NO synthase in wild-type mice attenuated vascular AT2 expression without affecting AT1. CONCLUSIONS: These findings provide direct evidence for CRP-induced hypertension, and they further identify a novel underlying mechanism involving downregulation of AT2 related to NO deficiency.

What does minor elevation of C-reactive protein signify?

Reports of the predictive value of minor elevation of serum C-reactive protein (CRP) levels (between 3 and 10 mg/L) for atherosclerotic events have generated considerable interest, as well as a degree of controversy and confusion. CRP concentrations in this range are found in about one third of the American population. To better understand the mechanisms underlying minor elevation of CRP, we have surveyed its reported associations with a variety of states and conditions. It has become clear that even minimal environmental irritants and inflammatory stimuli elicit a minor CRP response. Minor CRP elevation has been found associated with a number of genetic polymorphisms, with membership in different demographic and socioeconomic groups, with a variety of dietary patterns and with many medical conditions that are not apparently inflammatory. Finally, minor CRP elevation bears negative prognostic implications for many conditions, particularly age-related diseases, and predicts mortality in both diseased and apparently healthy individuals. In sum, minor CRP elevation is associated with a great many diverse conditions, some of which are, or may prove to be, causal. Many of these reported associations imply a mild degree of tissue stress or injury, suggesting the hypothesis that the presence of distressed cells, rather than a resulting inflammatory response, is commonly the stimulus for CRP production.

FcgammaRIIB mediates C-reactive protein inhibition of endothelial NO synthase.

C-reactive protein (CRP) is an acute-phase reactant that is positively correlated with cardiovascular disease risk and endothelial dysfunction. Whether CRP has direct actions on endothelium and the mechanisms underlying such actions are unknown. Here we show in cultured endothelium that CRP prevents endothelial NO synthase (eNOS) activation by diverse agonists, resulting in the promotion of monocyte adhesion. CRP antagonism of eNOS occurs nongenomically and is attributable to blunted eNOS phosphorylation at Ser1179. Okadaic acid or knockdown of PP2A by short-interference RNA reverses CRP antagonism of eNOS, indicating a key role for the phosphatase. Aggregated IgG, the known ligand for Fcgamma receptors, causes parallel okadaic acid-sensitive loss of eNOS function, FcgammaRIIB expression is demonstrable in endothelium, and heterologous expression studies reveal that CRP antagonism of eNOS requires FcgammaRIIB. In FcgammaRIIB(+/+) mice, CRP blunts acetylcholine-induced increases in carotid artery vascular conductance; in contrast, CRP enhances acetylcholine responses in FcgammaRIIB(-/-) mice. Thus FcgammaRIIB mediates CRP inhibition of eNOS via PP2A, providing a mechanistic link between CRP and endothelial dysfunction.

An intact phosphocholine binding site is necessary for transgenic rabbit C-reactive protein to protect mice against challenge with platelet-activating factor.

C-reactive protein (CRP), an acute phase protein in humans and rabbits, is part of the innate immune system. The role of CRP in host defense has been thought to be largely due to its ability to bind phosphocholine, activate complement, and interact with IgGRs (FcgammaRs). We have shown previously that transgenic rabbit CRP (rbCRP) protects mice from lethal challenges with platelet-activating factor (PAF). To investigate the mechanism of this protection, we created additional lines of transgenic mice that express either wild-type rbCRP, a variant of rbCRP with altered complement activation activity (Y175A), or a variant of rbCRP unable to bind phosphocholine (F66Y/E81K). In the current study, these lines were challenged with a single injection of PAF and their survival monitored. Mice expressing wild-type and Y175A rbCRP were protected against challenge by PAF whereas mice expressing F66Y/E81K rbCRP were not. Treatment with cobra venom factor did not affect survival, confirming the results with the Y175A rbCRP variant and indicating that complement activation was not required to mediate protection. Both wild-type rbCRP and Y175A rbCRP were capable of binding PAF in vitro whereas F66Y/E81K rbCRP was not. Although other interpretations are possible, our results suggest that the protective effect of rbCRP against PAF is due to sequestration of PAF.

Role of C-reactive protein in atherogenesis: can the apolipoprotein E knockout mouse provide the answer?

OBJECTIVE: Human C-reactive protein (CRP) was reported to accelerate atherosclerotic lesion development in male but not in female apolipoprotein E (apoE) knockout mice. Here, mice expressing rabbit CRP (rbCRP) were crossbred onto apoE knockout animals, and the effect on atherogenesis was studied. METHODS AND RESULTS: Hemolytic complement activity could not be detected in apoE knockout mice. Furthermore, in contrast to human complement, neither rabbit nor human CRP complexed to modified low-density lipoprotein-activated murine complement. At 52 weeks, rbCRP levels were similar in male and female transgenic animals. Serum cholesterol levels were equivalent in female animals irrespective of rbCRP expression, whereas rbCRP-positive males had significantly higher serum cholesterol levels than the rbCRP-negative counterparts. All mice exhibited extensive atherosclerotic lesions, as studied en face, and no differences were noted between rbCRP-negative and rbCRP-positive animals. Atherosclerotic luminal obstruction of aortic arch and first-order neck branches did not differ significantly between rbCRP-positive and rbCRP-negative mice. There was no correlation between rbCRP levels and atherosclerotic lesion formation. CONCLUSIONS: No marked effect of rbCRP on the formation of moderately advanced atherosclerotic lesions could be discerned in the apoE knockout mouse. Because of the oddities of the mouse complement system, however, this may not be a good model to investigate the role of CRP in human atherosclerosis.

C-reactive Protein.

C-reactive protein (CRP) is a phylogenetically highly conserved plasma protein, with homologs in vertebrates and many invertebrates, that participates in the systemic response to inflammation. Its plasma concentration increases during inflammatory states, a characteristic that has long been employed for clinical purposes. CRP is a pattern recognition molecule, binding to specific molecular configurations that are typically exposed during cell death or found on the surfaces of pathogens. Its rapid increase in synthesis within hours after tissue injury or infection suggests that it contributes to host defense and that it is part of the innate immune response. Recently, an association between minor CRP elevation and future major cardiovascular events has been recognized, leading to the recommendation by the Centers for Disease Control and the American Heart Association that patients at intermediate risk of coronary heart disease might benefit from measurement of CRP. This review will largely focus on our current understanding of the structure of CRP, its ligands, the effector molecules with which it interacts, and its apparent functions.

SREBP-1c and Sp1 interact to regulate transcription of the gene for phosphoenolpyruvate carboxykinase (GTP) in the liver.

The sterol regulatory element-binding protein-1c (SREBP-1c), as well as SREBP-1a and SREBP-2, inhibit transcription of the gene encoding the cytosolic form of phosphoenolpyruvate carboxykinase (GTP) (PEPCK-C). There are two SREBP regulatory elements (SREs) in the PEPCK-C gene promoter (-322 to -313 and -590 to -581). The SRE at -590 overlaps an Sp1 site on the opposite strand of the DNA. These SREs bound SREBP-1a and SREBP-1c with low affinity but the addition of purified upstream stimulatory activity enhanced the binding of SREBP-1 to both of these sites. Mutating these SREs increased both unstimulated (5-fold) and protein kinase A-stimulated transcription (8-27-fold) from the PEPCK-C gene promoter; this was lost when both SREs were mutated. The SRE at -590 differs by a single base pair from the SRE in the low density lipoprotein (LDL) receptor gene (T in the PEPCK-C gene promoter at -582, compared with an A in the SRE of the gene for the LDL receptor promoter). Introduction of the LDL receptor SRE into the PEPCK-C gene promoter increased SREBP-1c binding and caused a 10-fold enhancement of basal transcription from the promoter, rather than an inhibition as observed with the SRE in the PEPCK-C gene promoter. The T/A change does not alter the binding of Sp1 to its site on the opposite strand of the DNA. Sp1 bound to the promoter independently of SREBP-1c but competed with SREBP-1c for binding. Sp1 does not bind to the SRE at -322. Chromatin immunoprecipitation analysis, using rat hepatocytes, demonstrated that SREBP-1 and Sp1 were associated in vivo with putative regulatory regions corresponding to the SREs in the PEPCK-C gene promoter. We propose that insulin represses transcription of the gene for PEPCK-C by inducing SREBP-1c production in the liver, which interferes with the stimulatory effect of Sp1 at -590 of the PEPCK-C gene promoter.

Transcription factor c-Rel enhances C-reactive protein expression by facilitating the binding of C/EBPbeta to the promoter.

Induction of C-reactive protein (CRP) synthesis in hepatocytes by cytokines occurs at the transcriptional level. In Hep3B cells, the transcription factors C/EBPbeta, STAT3, and Rel p50 have been shown to participate in this process. A C/EBP binding site centered at -53 and an overlapping nonconsensus kappaB site on the promoter are critical for CRP expression. We have previously found that an oligonucleotide containing a kappaB site diminished binding of C/EBPbeta to the C/EBP site, suggesting that unidentified Rel proteins present in Hep3B nuclei facilitate the formation of C/EBPbeta-complexes. The current studies were undertaken to determine which of the five Rel proteins, p50/p65/p52/c-Rel/RelB, play such a role. Mutation of the nonconsensus kappaB site did not abolish binding of C/EBPbeta to its binding site, indicating that this site was not necessary for the formation of C/EBPbeta-complexes. Depletion of Rel proteins from Hep3B nuclei led to decreased formation of C/EBPbeta-complexes on a CRP promoter-derived oligonucleotide that contained only the intact C/EBP binding site but not the nonconsensus kappaB site. This finding indicates that Rel proteins are involved in the binding of C/EBPbeta to its binding site by a kappaB site-independent mechanism. Electrophoretic mobility shift assays (EMSAs) revealed that it was c-Rel that facilitated formation of C/EBPbeta-complexes and that c-Rel bound directly to C/EBPbeta-complexes formed on the C/EBP site. Cotransfection of c-Rel enhanced the induction of CRP promoter-driven luciferase activity and enhanced endogenous CRP expression in cells transfected with C/EBPbeta. We conclude that c-Rel regulates CRP expression without the requirement of binding to a kappaB site, and binds directly to C/EBPbeta to facilitate the binding of C/EBPbeta to the CRP promoter.

The phosphocholine and the polycation-binding sites on rabbit C-reactive protein are structurally and functionally distinct.

C-reactive protein (CRP) is an acute phase protein in humans and rabbits that has the ability to bind a number of biologically important ligands including phosphocholine (PCh), histones, and polycations. In addition to this recognition function, ligand-complexed or aggregated CRP is capable of activating the classical complement pathway. We have generated two strains of transgenic mice in order to study CRP-binding to PCh and consequent complement activation. Based on crystallographic and mutagenesis studies in human CRP (huCRP), we mutated Phe66 and Glu81 in the rabbit CRP (rbCRP) gene and generated a strain of transgenic mice (F66Y/E81K), which expressed this variant form of rbCRP. We also mutated Tyr175 in rbCRP to generate transgenic mice which expressed a variant form of rbCRP (Y175A). In vitro, F66Y/E81K rbCRP purified from serum had dramatically reduced binding to PCh. Additionally F66Y/E81K rbCRP not only maintained its ability to bind polycations and histones, but also bound more avidly to specific histones and lysine polymers than wild type (wt) rbCRP. Y175A rbCRP was not able to activate complement when bound to pneumococcal C-polysaccharide (PnC), but was, along with F66Y/E81K and wild type rbCRP, able to activate complement when bound to a small lysine polymer or when directly adsorbed to a solid phase. This complement activation presumably occurs through the classical complement pathway as the three rbCRPs, adsorbed to a solid phase, bound C1q. Taken together, our results demonstrate that the PCh-binding and the polycation-binding sites on rbCRP are distinct but possibly overlapping. The conformational changes in the C1q-binding site of CRP to activate complement depend on the nature of the ligand and on the location of the ligand-binding site.

Overexpressed nuclear factor-kappaB can participate in endogenous C-reactive protein induction, and enhances the effects of C/EBPbeta and signal transducer and activator of transcription-3.

C-reactive protein (CRP), the prototypical human acute phase protein, is produced primarily by hepatocytes. Its expression is modestly induced by interleukin (IL)-6 in Hep3B cells while IL-1, which alone has no effect, synergistically enhances the effects of IL-6. In previous studies of the proximal CRP promoter, we found that signal transducer and activator of transcription-3 (STAT3) and C/EBPbeta -mediated IL-6-induced transcription and that Rel p50 acted synergistically with C/EBPbeta, in the absence of p65, to enhance CRP transcription. Neither a requirement nor a binding site for the classic nuclear factor (NF)-kappaB heterodimer p50/p65 were found. The current studies were undertaken to determine whether similar novel transcription factor interactions might regulate the endogenous CRP gene. Transiently overexpressed p50 or p65 induced CRP mRNA accumulation in Hep3B cells. The heterodimer p50/p65 was markedly more effective than p50 or p65 homodimers. Co-overexpression of p50 or p65 with C/EBPbeta or STAT3 synergistically enhanced CRP expression. Maximal expression was observed with overexpression of all four transcription factors; comparable effects were observed with IL-1beta treatment of cells overexpressing STAT3 + C/EBPbeta. Data from the Human Genome Project revealed 13 potential kappaB sites in the first 4000 bases of the CRP promoter, only one of which, centred at -2652, bound nuclear p50/p65 heterodimer activated by IL-1beta. Our findings indicate that classical NF-kappaB activation can participate in endogenous CRP induction, and that activated NF-kappaB may synergistically enhance the effects of C/EBPbeta and STAT3. They raise the possibility, not as yet established, that NF-kappaB activation may be responsible for the synergistic effect of IL-1beta on IL-6-induced CRP expression.

A C-reactive protein mutant that does not bind to phosphocholine and pneumococcal C-polysaccharide.

C-reactive protein (CRP), the major human acute-phase plasma protein, binds to phosphocholine (PCh) residues present in pneumococcal C-polysaccharide (PnC) of Streptococcus pneumoniae and to PCh exposed on damaged and apoptotic cells. CRP also binds, in a PCh-inhibitable manner, to ligands that do not contain PCh, such as fibronectin (Fn). Crystallographic data on CRP-PCh complexes indicate that Phe(66) and Glu(81) contribute to the formation of the PCh binding site of CRP. We used site-directed mutagenesis to analyze the contribution of Phe(66) and Glu(81) to the binding of CRP to PCh, and to generate a CRP mutant that does not bind to PCh-containing ligands. Five CRP mutants, F66A, F66Y, E81A, E81K, and F66A/E81A, were constructed, expressed in COS cells, purified, and characterized for their binding to PnC, PCh-BSA, and Fn. Wild-type and F66Y CRP bound to PnC with similar avidities, while binding of E81A and E81K mutants to PnC was substantially reduced. The F66A and F66A/E81A mutants did not bind to PnC. Identical results were obtained with PCh-BSA. In contrast, all five CRP mutants bound to Fn as well as did wild-type CRP. We conclude that Phe(66) is the major determinant of CRP-PCh interaction and is critical for binding of CRP to PnC. The data also suggest that the binding sites for PCh and Fn on CRP are distinct. A CRP mutant incapable of binding to PCh provides a tool to assess PCh-inhibitable interactions of CRP with its other biologically significant ligands, and to further investigate the functions of CRP in host defense and inflammation.