Apolipoprotein B100 is a suppressor of Staphylococcus aureus-induced innate immune responses in humans and mice.

Plasma lipoproteins such as LDL (low-density lipoprotein) are important therapeutic targets as they play a crucial role in macrophage biology and metabolic disorders. The impact of lipoprotein profiles on host defense pathways against Gram-positive bacteria is poorly understood. In this report, we discovered that human serum lipoproteins bind to lipoteichoic acid (LTA) from Staphylococcus aureus and thereby alter the immune response to these bacteria. Size-exclusion chromatography and solid-phase-binding analysis of serum revealed the direct interaction of LTA with apolipoproteins (Apo) B100, ApoA1, and ApoA2. Only ApoB100 and the corresponding LDL exerted biological effects as this binding significantly inhibited LTA-induced cytokine releases from human and murine immune cells. Serum from hypercholesterolemic mice or humans significantly diminished cytokine induction in response to S. aureus or its LTA. Sera taken from the patients with familial hypercholesterolemia before and after ApoB100-directed immuno-apheresis confirmed that ApoB100 inhibited LTA-induced inflammation in humans. In addition, mice in which LDL secretion was pharmacologically inhibited, displayed significantly increased serum cytokine levels upon infection with S. aureus in vivo. The present study identifies ApoB100 as an important suppressor of innate immune activation in response to S. aureus and its LTA.

Critical evaluation of urine-based PCR assay for diagnosis of Lyme borreliosis.

Many approaches were made in recent years to establish urine PCR as a diagnostic tool for Lyme borreliosis, but results are contradictory. In the present study, a standardized protocol spiking urine from healthy donors with a defined amount of whole Borrelia or Borrelia DNA was established. The development of a nested real-time PCR targeting ospA enabled a highly sensitive and quantitative analysis of these samples. We show the following. (i) Storage of spiked urine samples for up to 6 months at--20 degrees C had no negative effect on spike recovery. (ii) Centrifugation of 10 ml of urine at 40,000 x g for 30 min resulted in a concentration of both spikes, i.e., whole Borrelia and DNA. (iii) The inhibition of DNA spike recovery in 48% (11 of 23 samples) of urine samples tested could be attributed to nuclease activity. This was abrogated by alkalizing the urine or by working with the samples on ice. Despite optimized conditions, analysis of urine samples of 12 patients with erythema migrans, the clinical stage considered to be associated with the highest bacterial load, revealed a positive result in only one sample. All 12 samples were negative by an alternative PCR targeting flagellin. The results of our study support doubts that urine is a suitable material for diagnosis of Lyme borreliosis.

In vitro non-natural amino acid mutagenesis using a suppressor tRNA generated by the cis-acting hepatitis delta virus ribozyme.

In vitro non-natural amino acid mutagenesis requires aminoacyl-charged suppressor transfer RNAs which read an internal stop codon. For the synthesis of aminoacyl-tRNAs loaded with non-natural amino acids, T4 RNA ligase is used to ligate a chemically synthesised aminoacyl-dinucleotide to a truncated 74mer tRNA(-CA) lacking the two 3' end nucleotides. The 74mer tRNA(-CA) in turn is generated by run-off transcription from a linearised plasmid encoding the tRNA sequence under control of the T7 promoter. Transcripts with heterogeneous ends are commonly obtained, which interfere with subsequent reactions such as ligation or translation. Here we report an improved procedure for the generation and chromatographic purification of large amounts of homogeneous 3' end tRNA(-CA) by hepatitis delta virus ribozyme cis-cleavage and the first application of this tRNA to in vitro non-natural amino acid mutagenesis. Stop codon suppression is increased compared to conventionally synthesised suppressor tRNA; 2.5 microg of mutated protein was synthesised in a 50 microl batch reaction.

GM-CSF restores innate, but not adaptive, immune responses in glucocorticoid-immunosuppressed human blood in vitro.

Infection remains the major complication of immunosuppressive therapy in organ transplantation. Therefore, reconstitution of the innate immunity against infections, without activation of the adaptive immune responses, to prevent graft rejection is a clinically desirable status in transplant recipients. We found that GM-CSF restored TNF mRNA and protein expression without inducing IL-2 production and T cell proliferation in glucocorticoid-immunosuppressed blood from either healthy donors or liver transplant patients. Gene array experiments indicated that GM-CSF selectively restored a variety of dexamethasone-suppressed, LPS-inducible genes relevant for innate immunity. A possible explanation for the lack of GM-CSF to restore T cell proliferation is its enhancement of the release of IL-1betaR antagonist, rather than of IL-1beta itself, since exogenously added IL-1beta induced an IL-2-independent Con A-stimulated proliferation of glucocorticoid-immunosuppressed lymphocytes. Finally, to test the in vivo relevance of our findings, we showed that GM-CSF restored the survival of dexamethasone- or cyclosporine A-immunosuppressed mice from an otherwise lethal infection with Salmonella typhimurium. In addition to this increased resistance to infection, GM-CSF did not induce graft rejection of a skin allotransplant in cyclosporine A-immunosuppressed mice. The selective restoration potential of GM-CSF suggests its therapeutic use in improving the resistance against infections upon organ transplantation.

Cyclic AMP increases endogenous granulocyte colony-stimulating factor formation in monocytes and THP-1 macrophages despite attenuated TNF-alpha formation.

The cytokine granulocyte colony-stimulating factor (G-CSF) is in broad clinical use to treat neutropenia, and trials on its use in immunosuppressed conditions and infections are ongoing. To apply G-CSF effectively, it is crucial to understand the regulation and distribution of its endogenous formation. Since G-CSF release is mediated, at least in part, by TNF-alpha formation, we investigated whether drugs suppressing TNF-alpha also impair G-CSF production. Surprisingly, G-CSF formation was enhanced in lipopolysaccharide (LPS)-stimulated blood from a pentoxifylline-treated patient. In the presence of dibutyryl-cAMP, forskolin, tolafentrine or 3-isobutyl-1-methylxanthine, LPS-induced G-CSF formation was enhanced in THP-1 cells, primary monocytes and whole blood. Correspondingly,rp-8-bromo-cAMP suppressed LPS-induced G-CSF release. Addition of prostaglandin E(2) enhanced and indomethacin suppressed G-CSF formation. Reporter gene studies showed that dibutyryl-cAMP enhanced LPS-induced G-CSF promoter activity, indicating a transcriptional up-regulation. Furthermore, disruption of a newly identified putative cAMP-responsive element (CRE) in the G-CSF promoter demonstrated the regulatory role for G-CSF gene transcription. In conclusion, endogenous G-CSF formation critically depends on both TNF-alpha and cyclooxygenase products, exerting effects via cAMP and the CRE in the G-CSF promoter. This might have bearing for drug side effects, putative G-CSF mimetics and our understanding of G-CSF immunobiology.