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.     

Role of the property of C-reactive protein to activate the classical pathway of complement in protecting mice from pneumococcal infection

C-reactive protein (CRP) is not an acute-phase protein in mice, and therefore, mice are widely used to investigate the functions of human CRP. It has been shown that CRP protects mice from pneumococcal infection, and an active complement system is required for full protection. In this study, we assessed the contribution of CRP's ability of activating the classical pathway of complement in the protection of mice from lethal infection with virulent Streptococcus pneumoniae type 3. We used two CRP mutants, Y175A and K114A. The Y175A CRP does not bind C1q and does not activate complement in human serum. The K114A CRP binds C1q and activates complement more efficiently than wild-type CRP. Passively administered, both CRP mutants and the wild-type CRP protected mice from infection equally. Infected mice injected with wild-type or mutant CRP had reduced bacteremia, resulting in lower mortality and increased longevity compared with mice that did not receive CRP. Thus, the protection of mice was independent of CRP-mediated activation of the classical pathway of complement. To confirm that human CRP does not differentiate between human and mouse complement, we analyzed the binding of human CRP to mouse C1q. Surprisingly, CRP did not react with mouse C1q, although both mutant and wild-type CRP activated mouse C3, indicating species specificity of CRP-C1q interaction. We conclude that the mouse is an unfit animal for exploring CRP-mediated activation of the classical complement pathway, and that the characteristic of CRP to activate the classical complement pathway has no role in protecting mice from infection.     

Human C-reactive protein protects mice from Streptococcus pneumoniae infection without binding to pneumococcal C-polysaccharide

Human C-reactive protein (CRP) protects mice from lethality after infection with virulent Streptococcus pneumoniae type 3. For CRP-mediated protection, the complement system is required; however, the role of complement activation by CRP in the protection is not defined. Based on the in vitro properties of CRP, it has been assumed that protection of mice begins with the binding of CRP to pneumococcal C-polysaccharide on S. pneumoniae and subsequent activation of the mouse complement system. In this study, we explored the mechanism of CRP-mediated protection by utilizing two CRP mutants, F66A and F66A/E81A. Both mutants, unlike wild-type CRP, do not bind live virulent S. pneumoniae. We found that passively administered mutant CRP protected mice from infection as effectively as the wild-type CRP did. Infected mice injected with wild-type CRP or with mutant CRP lived longer and had lower mortality than mice that did not receive CRP. Extended survival was caused by the persistence of reduced bacteremia in mice treated with any CRP. We conclude that the CRP-mediated decrease in bacteremia and the resulting protection of mice are independent of an interaction between CRP and the pathogen and therefore are independent of the ability of CRP to activate mouse complement. It has been shown previously that the Fcgamma receptors also do not contribute to such CRP-mediated protection. Combined data lead to the speculation that CRP acts on the effector cells of the immune system to enhance cell-mediated cytotoxicity and suggest investigation into the possibility of using CRP-loaded APC-based strategy to treat microbial infections.     

Probing the phosphocholine-binding site of human C-reactive protein by site-directed mutagenesis.

Human C-reactive protein (CRP) can activate the classical pathway of complement and function as an opsonin only when it is complexed to an appropriate ligand. Most known CRP ligands bind to the phosphocholine (PCh)-binding site of the protein. In the present study, we used oligonucleotide-directed site-specific mutagenesis to investigate structural determinants of the PCh-binding site of CRP. Eight mutant recombinant (r) CRP, Y40F; E42Q; Y40F, E42Q; K57Q; R58G; K57Q, R58G; W67K; and K57Q, R58G, W67K were constructed and expressed in COS cells. Wild-type and all mutant rCRP except for the W67K mutants bound to solid-phase PCh-substituted bovine serum albumin (PCh-BSA) with similar apparent avidities. However, W67K rCRP had decreased avidity for PCh-BSA and the triple mutant, K57Q, R58G, W67K, failed to bind PCh-BSA. Inhibition experiments using PCh and dAMP as inhibitors indicated that both Lys-57 and Arg-58 contribute to PCh binding. They also indicated that Trp-67 provides interactions with the choline group. The Y40F and E42Q mutants were found to have increased avidity for fibronectin compared to wild-type rCRP. We conclude that the residues Lys-57, Arg-58, and Trp-67 contribute to the structure of the PCh-binding site of human CRP. Residues Tyr-40 and Glu-42 do not appear to participate in the formation of the PCh-binding site of CRP, however, they may be located in the vicinity of the fibronectin-binding site of CRP.     

Origin of apparent negative cooperativity of F(1)-ATPase

In order to get insight into the origin of apparent negative cooperativity observed for F(1)-ATPase, we compared ATPase activity and ATPMg binding of mutant subcomplexes of thermophilic F(1)-ATPase, alpha((W463F)3)beta((Y341W)3)gamma and alpha((K175A/T176A/W463F)3)beta((Y341W)3)gamma. For alpha((W463F)3)beta((Y341W)3)gamma, apparent K(m)'s of ATPase kinetics (4.0 and 233 microM) did not agree with apparent K(m)'s deduced from fluorescence quenching of the introduced tryptophan residue (on the order of nM, 0.016 and 13 microM). On the other hand, in case of alpha((K175A/T176A/W463F)3)beta((Y341W)3)gamma, which lacks noncatalytic nucleotide binding sites, the apparent K(m) of ATPase activity (10 microM) roughly agreed with the highest K(m) of fluorescence measurements (27 microM). The results indicate that in case of alpha((W463F)3)beta((Y341W)3)gamma, the activating effect of ATP binding to noncatalytic sites dominates overall ATPase kinetics and the highest apparent K(m) of ATPase activity does not represent the ATP binding to a catalytic site. In case of alpha((K175A/T176A/W463F)3)beta((Y341W)3)gamma, the K(m) of ATPase activity reflects the ATP binding to a catalytic site due to the lack of noncatalytic sites. The Eadie-Hofstee plot of ATPase reaction by alpha((K175A/T176A/W463F)3)beta((Y341W)3)gamma was rather linear compared with that of alpha((W463F)3)beta((Y341W)3)gamma, if not perfectly straight, indicating that the apparent negative cooperativity observed for wild-type F(1)-ATPase is due to the ATP binding to catalytic sites and noncatalytic sites. Thus, the frequently observed K(m)'s of 100-300 microM and 1-30 microM range for wild-type F(1)-ATPase correspond to ATP binding to a noncatalytic site and catalytic site, respectively.     

Exposing a hidden functional site of C-reactive protein by site-directed mutagenesis

C-reactive protein (CRP) is a cyclic pentameric protein whose major binding specificity, at physiological pH, is for substances bearing exposed phosphocholine moieties. Another pentameric form of CRP, which exists at acidic pH, displays binding activity for oxidized LDL (ox-LDL). The ox-LDL-binding site in CRP, which is hidden at physiological pH, is exposed by acidic pH-induced structural changes in pentameric CRP. The aim of this study was to expose the hidden ox-LDL-binding site of CRP by site-directed mutagenesis and to generate a CRP mutant that can bind to ox-LDL without the requirement of acidic pH. Mutation of Glu(42), an amino acid that participates in intersubunit interactions in the CRP pentamer and is buried, to Gln resulted in a CRP mutant (E42Q) that showed significant binding activity for ox-LDL at physiological pH. For maximal binding to ox-LDL, E42Q CRP required a pH much less acidic than that required by wild-type CRP. At any given pH, E42Q CRP was more efficient than wild-type CRP in binding to ox-LDL. Like wild-type CRP, E42Q CRP remained pentameric at acidic pH. Also, E42Q CRP was more efficient than wild-type CRP in binding to several other deposited, conformationally altered proteins. The E42Q CRP mutant provides a tool to investigate the functions of CRP in defined animal models of inflammatory diseases including atherosclerosis because wild-type CRP requires acidic pH to bind to deposited, conformationally altered proteins, including ox-LDL, and available animal models may not have sufficient acidosis or other possible modifiers of the pentameric structure of CRP at the sites of inflammation.     

Probing the 2,4-dichlorophenoxyacetate/alpha-ketoglutarate dioxygenase substrate-binding site by site-directed mutagenesis and mechanism-based inactivation

TfdA is an Fe(II)- and alpha-ketoglutarate- (alphaKG-) dependent dioxygenase that hydroxylates the herbicide 2,4-dichlorophenoxyacetic acid (2,4-D) producing a hemiacetal that spontaneously decomposes to 2,4-dichlorophenol and glyoxylate. On the basis of a recently published TfdA structural model [Elkins et al. (2002) Biochemistry 41, 5185-5192], His214, Lys71, Arg278, and the backbone amide of Ser117 are suggested to bind the 2,4-D carboxylate; Lys95 and possibly Lys71 are hypothesized to interact with the 2,4-D ether atom; and Arg274 and Thr141 are suspected to bind alphaKG. TfdA variants with substitutions at these and other positions were purified and characterized in order to explore the roles of these residues in catalysis. The K71L, K71Q, K95L, K95Q, R274Q, R274L, and R278Q variants exhibited significantly increased 2,4-D K(m), alphaKG K(m), and alphaKG K(d) values, consistent with their proposed roles in substrate binding. A protease-sensitive site was successfully eliminated in the R78Q variant, which also exhibited decreased affinity for 2,4-D. In contrast, the Y81F, Y126F, T141V, Y169F, and Y244F variants showed only modest changes in their kinetics. An observed 4-fold lower K(m) of the K95L variant compared to wild-type protein with the alternative substrate 2,4-dichlorocinnamic acid provided additional evidence for an interaction between Lys95 and the 2,4-D ether atom. Phenylpropiolic acid was identified as a mechanism-based inactivator of the enzyme [K(i) = 38.1 +/- 6.0 microM and k(inact)(max) = 2.3 +/- 0.1 min(-1)]. This acetylenic compound covalently modifies a peptide (166-AEHYALNSR-174) that is predicted to form one side of the substrate-binding pocket. The K95L variant of TfdA was not inactivated by phenylpropiolic acid, providing added support that Lys95 is present at the active site. These results support the identity of suspected substrate-binding residues derived from structural modeling studies and extend our understanding of the oxidative chemistry carried out by TfdA.     

GTK tyrosine kinase-induced alteration of IRS-protein signalling in insulin producing cells

BACKGROUND: Insulin receptor substrate proteins (IRS) mediate various effects of insulin, including regulation of glucose homeostasis, cell growth and survival. To understand the underlying mechanisms explaining the effects of the Src-related tyrosine kinase GTK on beta-cell proliferation and survival, insulin-signalling pathways involving IRS-1 and IRS-2 were studied in islet cells and RINm5F cells overexpressing wild-type and two different mutants of the SRC-related tyrosine kinase GTK. MATERIALS AND METHODS: Islets isolated from transgenic mice and RINm5F cells overexpressing wild-type and mutant GTK were analysed for IRS-1, IRS-2, SHB, AKT and ERK phosphorylation/activity by Western blot analysis. RESULTS: RINm5F cells expressing the kinase active mutant Y504F-GTK and islet cells from GTK(Y504F) -transgenic mice exhibited reduced insulin-induced tyrosine phosphorylation of IRS-1 and IRS-2. In RINm5F cells, the diminished IRS-phosphorylation was accompanied by a reduced insulin-stimulated activation of phosphatidylinositol 3-kinase (PI3K), AKT and Extracellular Signal-Regulated Kinase, partly due to an increased basal activity. In addition, increased tyrosine phosphorylation of the SHB SH2 domain-adaptor protein and its association with IRS-2, IRS-1 and focal adhesion kinase was observed in these cells. RINm5F cells overexpressing wild-type GTK also exhibited reduced activation of IRS-2, PI3K and AKT, whereas cells expressing a GTK mutant with lower kinase activity (GTK(Y394F)) exhibited insignificantly altered responses to insulin compared to the mock transfected cells. Moreover, GTK was shown to associate with and phosphorylate SHB in transiently transfected COS-7 cells, indicating that SHB is a specific substrate for GTK. CONCLUSIONS: The results suggest that GTK signals via SHB to modulate insulin-stimulated pathways in beta cells and this may explain previous results showing an increased beta-cell mass in GTK-transgenic mice.     

Protection from Streptococcus pneumoniae infection by C-reactive protein and natural antibody requires complement but not Fc gamma receptors

Streptococcus pneumoniae is an important human pathogen and the most common cause of community-acquired pneumonia. Both adaptive and innate immune mechanisms provide protection from infection. Innate immunity to S. pneumoniae in mice is mediated by naturally occurring anti-phosphocholine (PC) Abs and complement. The human acute-phase reactant C-reactive protein (CRP) also protects mice from lethal S. pneumoniae infection. CRP and anti-PC Ab share the ability to bind to PC on the cell wall C-polysaccharide of S. pneumoniae and to activate complement. CRP and IgG anti-PC also bind to Fc gamma R. In this study, Fc gamma R- and complement-deficient mice were used to compare the mechanisms of protection conferred by CRP and anti-PC Ab. Injection of CRP protected wild-type, FcR gamma-chain-, Fc gamma RIIb-, and Fc gamma RIII-deficient mice from infection. Complement was required for the protective effect of CRP as cobra venom factor treatment eliminated the effect of CRP in both gamma-chain-deficient and wild-type mice, and CRP failed to protect C3- or C4-deficient mice from infection. Unexpectedly, gamma-chain-deficient mice were extremely sensitive to pneumococcal infection. This sensitivity was associated with low levels of natural anti-PC Ab. Gamma-chain-deficient mice immunized with nonencapsulated S. pneumoniae produced both IgM- and IgG PC-specific Abs, were protected from infection, and were able to clear the bacteria from the bloodstream. The protection provided by immunization was eliminated by complement depletion. The results show that in this model of systemic infection with highly virulent S. pneumoniae, protection from lethality by CRP and anti-PC Abs requires complement, but not Fc gamma R.     

Transgenic mice expressing a fully nontoxic diphtheria toxin mutant, not CRM197 mutant, acquire immune tolerance against diphtheria toxin

We previously developed a method termed "toxin receptor-mediated cell knockout" (TRECK). By the TRECK method, a single or repeated shot(s) of diphtheria toxin (DT) conditionally ablates a specific cell population from transgenic mice expressing the DT receptor transgene under the control of a cell type-specific promoter. In some cases of TRECK, frequent and high-dose administration of DT is required, raising the concern that these frequent injections of DT could cause production of anti-DT antibody, which would neutralize further DT administration. To solve this problem, we aimed to generate transgenic mice genetically expressing a nontoxic DT mutant, with the expectation that they may naturally acquire immune tolerance to DT. Unexpectedly, the G52E DT mutant, which is well known as the nontoxic DT variant cross reacting material 197 (CRM197), exhibited cytotoxicity in yeast and mammalian cells. Cytotoxicity of CRM197 was abrogated in cells mutated for elongation factor 2 (EF-2), indicating that CRM197 exerts its toxic effects through EF-2, similar to wild-type DT. On the other hand, the K51E/E148K DT mutant exhibited no detectable cytotoxicity. This led us to successfully obtain DT gene transgenic mice, which exhibited no histological abnormalities, and indeed acquired immune tolerance to DT.     

E2F1 Has Both Oncogenic and Tumor-Suppressive Properties in a Transgenic Model

Using a transgenic mouse model expressing the E2F1 gene under the control of a keratin 5 (K5) promoter, we previously demonstrated that increased E2F1 activity can promote tumorigenesis by cooperating with either a v-Ha-ras transgene to induce benign skin papillomas or p53 deficiency to induce spontaneous skin carcinomas. We now report that as K5 E2F1 transgenic mice age, they are predisposed to develop spontaneous tumors in a variety of K5-expressing tissues, including the skin, vagina, forestomach, and odontogenic epithelium. On the other hand, K5 E2F1 transgenic mice are found to be resistant to skin tumor development following a two-stage carcinogenesis protocol. Additional experiments suggest that this tumor-suppressive effect of E2F1 occurs at the promotion stage and may involve the induction of apoptosis. These findings demonstrate that increased E2F1 activity can either promote or inhibit tumorigenesis, dependent upon the experimental context.     

A mutant of human papillomavirus type 16 E6 deficient in binding alpha-helix partners displays reduced oncogenic potential in vivo

Human papillomaviruses (HPVs) are small DNA tumor viruses that are the causative agent of warts and are associated with many anogenital cancers. The viral gene encoding the E6 protein has been found to be involved in HPV oncogenesis. E6 is known to inactivate the cellular tumor suppressor, p53. In addition, E6 has been shown to bind to a variety of other cellular proteins. The focus of this study was to determine what role the interactions of E6 with a subset of cellular proteins which contain a common alpha-helical domain in their E6 binding region (alpha-helix partners) play in E6-mediated phenotypes. We generated transgenic mice expressing a mutant of E6, E6(I128T), which is defective for binding at least a subset of the alpha-helix partners, including E6AP, the ubiquitin ligase that mediates E6-dependent degradation of the p53 protein, to determine whether binding of alpha-helix partners plays a role in E6-mediated activities in vivo. Unlike mice expressing the wild-type E6 (strain K14E6(WT)), the mice expressing E6(I128T) lacked the ability to alter the radiation-induced block to DNA synthesis and promote the formation of benign skin tumors in conjunction with chemical carcinogens. Additionally, they displayed reduced levels of skin hyperplasia, spontaneous skin tumors, and tumor progression activity compared to those of the K14E6(WT) mice. From these results, we conclude that a domain in E6 that mediates alpha-helix partner binding is critical for E6-induced phenotypes in transgenic mice.     

Skin hyperproliferation and susceptibility to chemical carcinogenesis in transgenic mice expressing E6 and E7 of human papillomavirus type 38

The oncoproteins E6 and E7 of human papillomavirus type 38 (HPV38) display several transforming activities in vitro, including immortalization of primary human keratinocytes. To evaluate the oncogenic activities of the viral proteins in an in vivo model, we generated transgenic mice expressing HPV38 E6 and E7 under the control of the bovine homologue of the human keratin 10 (K10) promoter. Two distinct lines of HPV38 E6/E7-expressing transgenic mice that express the viral genes at different levels were obtained. In both lines, HPV38 E6 and E7 induced cellular proliferation, hyperplasia, and dysplasia in the epidermis. The rate of occurrence of these events was proportional to the levels of HPV38 E6 and E7 expression in the two transgenic lines. Exposure of the epidermis of nontransgenic mice to UV led to p21WAF1 accumulation and cell cycle arrest. In contrast, keratinocytes from transgenic mice continued to proliferate and were not positive for p21WAF1, indicating that cell cycle checkpoints are altered in keratinocytes expressing the viral genes. Although the HPV38 E6/E7-expressing transgenic mice did not develop spontaneous tumors during their life span, two-stage carcinogen treatment led to a high incidence of papillomas, keratoacanthomas, and squamous-cell carcinomas in HPV38 mice compared with nontransgenic animals. Together, these data show that HPV38 E6 and E7 display transforming properties in vivo, providing further support for the role of HPV38 in carcinogenesis.     

Cytochrome b5 reductase: role of the si-face residues, proline 92 and tyrosine 93, in structure and catalysis

The conserved sequence motif "RxY(T)(S)xx(S)(N)" coordinates flavin binding in NADH:cytochrome b(5) reductase (cb(5)r) and other members of the flavin transhydrogenase superfamily of oxidoreductases. To investigate the roles of Y93, the third and only aromatic residue of the "RxY(T)(S)xx(S)(N)" motif, that stacks against the si-face of the flavin isoalloxazine ring, and P92, the second residue in the motif that is also in close proximity to the FAD moiety, a series of rat cb(5)r variants were produced with substitutions at either P92 or Y93, respectively. The proline mutants P92A, G, and S together with the tyrosine mutants Y93A, D, F, H, S, and W were recombinantly expressed in E. coli and purified to homogeneity. Each mutant protein was found to bind FAD in a 1:1 cofactor:protein stoichiometry while UV CD spectra suggested similar secondary structure organization among all nine variants. The tyrosine variants Y93A, D, F, H, and S exhibited varying degrees of blue-shift in the flavin visible absorption maxima while visible CD spectra of the Y93A, D, H, S, and W mutants exhibited similar blue-shifted maxima together with changes in absorption intensity. Intrinsic flavin fluorescence was quenched in the wild type, P92S and A, and Y93H and W mutants while Y93A, D, F, and S mutants exhibited increased fluorescence when compared to free FAD. The tyrosine variants Y93A, D, F, and S also exhibited greater thermolability of FAD binding. The specificity constant (k(cat)/K(m)(NADH)) for NADH:FR activity decreased in the order wild type > P92S > P92A > P92G > Y93F > Y93S > Y93A > Y93D > Y93H > Y93W with the Y93W variant retaining only 0.5% of wild-type efficiency. Both K(s)(H4NAD) and K(s)(NAD+) values suggested that Y93A, F, and W mutants had compromised NADH and NAD(+) binding. Thermodynamic measurements of the midpoint potential (E degrees ', n = 2) of the FAD/FADH(2) redox couple revealed that the potentials of the Y93A and S variants were approximately 30 mV more positive than that of wild-type cb(5)r (E degrees ' = -268 mV) while that of Y93H was approximately 30 mV more negative. These results indicate that neither P92 nor Y93 are critical for flavin incorporation in cb(5)r and that an aromatic side chain is not essential at position 93, but they demonstrate that Y93 forms contacts with the FAD that effectively modulate the spectroscopic, catalytic, and thermodynamic properties of the bound cofactor.     

Genetic Immunization of Wild-Type and Hepatitis C Virus Transgenic Mice Reveals a Hierarchy of Cellular Immune Response and Tolerance Induction against Hepatitis C Virus Structural Proteins

To study the effect of genetic immunization on transgenic expression of hepatitis C virus (HCV) proteins, we evaluated the immunological response of HCV transgenic mice to HCV expression plasmids. FVB/n transgenic mice expressing HCV structural proteins (core, E1, and E2) and wild-type (WT) FVB/n mice were immunized intramuscularly with plasmids expressing core (pHCVcore) or core/E1/E2 (pHCVSt). After immunization, HCV-specific humoral and cellular immune response was studied. Both WT and transgenic mice immunized with either HCV construct produced antibodies and exhibited T-cell proliferative responses against core or envelope. In WT mice immunized with pHCVSt, cytotoxic T-lymphocyte (CTL) activities were detected against E2 but not against core or E1, whereas strong CTL activities against core could be detected in WT mice immunized with pHCVcore. In pHCVSt-immunized, transgenic mice, CTL activities against the core or envelope were completely absent, but core-specific CTL activities could be detected in pHCVcore-immunized transgenic mice. A similar pattern of immune responses was also observed in other mouse strains, including a transgenic line expressing human HLA-A2.1 molecules (AAD mice). Despite the presence of a peripheral cellular immunity against HCV, no liver pathology or lymphocytic infiltrate was observed in these transgenic mice. Our study suggests a hierarchy of CTL response against the HCV structural proteins (E2 > core > E1) in vivo when the proteins are expressed as a polyprotein. The HCV transgenic mice can be induced by DNA immunization to generate anti-HCV antibodies and anticore CTLs. However, they are tolerant at the CTL level against the E2 protein despite DNA immunization.     

Receptor-dependent metabolism of platelet-activating factor in murine macrophages.

Degradation of platelet-activating factor (PAF) was examined by incubating PAF with macrophages from PAF receptor-deficient mice. The degradation rate was halved as compared with wild-type mice. The reduction of the rate was comparable with the presence of a PAF antagonist WEB 2086 in wild-type cells. PAF was internalized rapidly (t(12) approximately 1 min) into wild-type macrophages. The PAF internalization was inhibited by the treatment of 0.45 m sucrose but was not affected by phorbol 12-myristate 13-acetate, suggesting that PAF internalizes into macrophages with its receptor in a clathrin-dependent manner. Internalized PAF was degraded into lyso-PAF with a half-life of 20 min. Treatment of concanavalin A inhibited the conversion of PAF into lyso-PAF, suggesting that uptake of PAF enhances PAF degradation. Lyso-PAF was subsequently metabolized into 1-alkyl-2-acyl-phosphatidylcholine. In addition, release of PAF acetylhydrolase from macrophages was enhanced when wild-type macrophages were stimulated with PAF but not from macrophages of PAF receptor-deficient mice. Thus, the PAF stimulation of macrophages leads to its degradation through both intracellular and extracellular mechanisms.     

Effect of hydrophobic mutations in the H2-H3 subdomain of prion protein on stability and conversion in vitro and in vivo

Prion diseases are fatal neurodegenerative diseases, which can be acquired, sporadic or genetic, the latter being linked to mutations in the gene encoding prion protein. We have recently described the importance of subdomain separation in the conversion of prion protein (PrP). The goal of the present study was to investigate the effect of increasing the hydrophobic interactions within the H2-H3 subdomain on PrP conversion. Three hydrophobic mutations were introduced into PrP. The mutation V209I associated with human prion disease did not alter protein stability or in vitro fibrillization propensity of PrP. The designed mutations V175I and T187I on the other hand increased protein thermal stability. V175I mutant fibrillized faster than wild-type PrP. Conversion delay of T187I was slightly longer, but fluorescence intensity of amyloid specific dye thioflavin T was significantly higher. Surprisingly, cells expressing V209I variant exhibited inefficient proteinase K resistant PrP formation upon infection with 22L strain, which is in contrast to cell lines expressing wild-type, V175I and T187I mPrPs. In agreement with increased ThT fluorescence at the plateau T187I expressing cell lines accumulated an increased amount of the proteinase K-resistant prion protein. We showed that T187I induces formation of thin fibrils, which are absent from other samples. We propose that larger solvent accessibility of I187 in comparison to wild-type and other mutants may interfere with lateral annealing of filaments and may be the underlying reason for increased conversion efficiency.     

Novel roles in human MD-2 of phenylalanines 121 and 126 and tyrosine 131 in activation of Toll-like receptor 4 by endotoxin

Potent mammalian cell activation by Gram-negative bacterial endotoxin requires sequential protein-endotoxin and protein-protein interactions involving lipopolysaccharide-binding protein, CD14, MD-2, and Toll-like receptor 4 (TLR4). TLR4 activation requires simultaneous binding of MD-2 to endotoxin (E) and the ectodomain of TLR4. We now describe mutants of recombinant human MD-2 that bind TLR4 and react with E.CD14 but do not support cellular responsiveness to endotoxin. The mutants F121A/K122A MD-2 and Y131A/K132A MD-2 react with E.CD14 only when co-expressed with TLR4. Single mutants K122A and K132A each react with E.CD14 +/- TLR4 and promote TLR4-dependent cell activation by endotoxin suggesting that Phe(121) and Tyr(131) are needed for TLR4-independent transfer of endotoxin from CD14 to MD-2 and also needed for TLR4 activation by bound E.MD-2. The mutant F126A MD-2 reacts as well as wild-type MD-2 with E.CD14 +/- TLR4. E.MD-2(F126A) binds TLR4 with high affinity (K(d) approximately 200 pm) but does not activate TLR4 and instead acts as a potent TLR4 antagonist, inhibiting activation of HEK/TLR4 cells by wild-type E.MD-2. These findings reveal roles of Phe(121) and Tyr(131) in TLR4-independent interactions of human MD-2 with E.CD14 and, together with Phe(126), in activation of TLR4 by bound E.MD-2. These findings strongly suggest that the structural properties of E.MD-2, not E alone, determine agonist or antagonist effects on TLR4.