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1	Purification of Recombinant C-Reactive Protein Mutants Thirumalai, Avinash, Singh, Sanjay K., Hammond, David J., Gang, Toh B., Ngwa, Donald N., Pathak, Asmita, Agrawal, Alok 01 April 2017 (has links) C-reactive protein (CRP) is an evolutionarily conserved protein, a component of the innate immune system, and an acute phase protein in humans. In addition to its raised level in blood in inflammatory states, CRP is also localized at sites of inflammation including atherosclerotic lesions, arthritic joints and amyloid plaque deposits. Results of in vivo experiments in animal models of inflammatory diseases indicate that CRP is an anti-pneumococcal, anti-atherosclerotic, anti-arthritic and an anti-amyloidogenic molecule. The mechanisms through which CRP functions in inflammatory diseases are not fully defined; however, the ligand recognition function of CRP in its native and non-native pentameric structural conformations and the complement-activating ability of ligand-complexed CRP have been suggested to play a role. One tool to understand the structure-function relationships of CRP and determine the contributions of the recognition and effector functions of CRP in host defense is to employ site-directed mutagenesis to create mutants for experimentation. For example, CRP mutants incapable of binding to phosphocholine are generated to investigate the importance of the phosphocholine-binding property of CRP in mediating host defense. Recombinant CRP mutants can be expressed in mammalian cells and, if expressed, can be purified from the cell culture media. While the methods to purify wild-type CRP are well established, different purification strategies are needed to purify various mutant forms of CRP if the mutant does not bind to either calcium or phosphocholine. In this article, we report the methods used to purify pentameric recombinant wild-type and mutant CRP expressed in and secreted by mammalian cells. C-reactive protein phosphocholine phosphoethanolamine Biomedical Sciences
2	The contribution of two phosphorylated surface modifications on the pathogenesis of Campylobacter upsaliensis Crowley, Shauna M Unknown Date No description available. Campylobacter upsaliensis pathogenesis phosphoramidate phosphocholine serum suceptibility adherence and invasion
3	CRP After 2004 Agrawal, Alok 01 January 2005 (has links) C-reactive protein (CRP) that has been conserved throughout evolution is a host-defense molecule. Its attraction towards phosphocholine-ligands, such as modified low-density lipoprotein, and apoptotic cells leads to the "masking" of these substances that have the capabilities to otherwise engage in deleterious activities. Complement activation by CRP complexes and the modulation by CRP of complement activation by its ligands add up to its beneficial effects. In the presence of CRP, production of membrane-damaging last product of the complement pathway is arrested. CRP is currently serving as an indicator of cardiovascular diseases, but to pinpoint the role of CRP in atherosclerosis, a drug that can lower cholesterol levels, but not the CRP levels, is needed for experimentation. atherosclerosis C-reactive protein complement phosphocholine Biomedical Sciences
4	C-REACTIVE PROTEIN: A STUDY OF ITS FUNCTIONAL DOMAINS USING TRANSGENIC MICE Black, Steven Gregory January 2005 (has links) No description available. Biology, General acute phase protein inflammation complement phosphocholine transgenic mice
5	Caractérisation in vivo du rôle de phosphatases de la famille PS2;1 à 3, marqueurs précoces de la carence en phosphate chez Arabidopsis thaliana / In vivo characterization of the role of phosphatases family PS2;1 to 3, early markers of phosphate deficiency in Arabidopsis thaliana Hanchi, Mohamed 28 November 2017 (has links) Le phosphate (Pi) est un macroélément essentiel au développement de la plante. Lors d'une carence en Pi, l'expression de plusieurs gènes est dérégulée permettant à la plante de s'adapter à ce type de stress abiotique. Chez Arabidopsis thaliana, la carence induit très fortement PS2;1 (At1g73010) et PS2;2 (At1g17710), deux phosphatases de type HAD. La fonction biochimique de ces deux protéines a été caractérisée précédemment in vitro, mais leur rôle in vivo reste à établir.Dans ce travail de thèse, nous avons examiné la fonction in planta de ces deux protéines en utilisant des approches de génétique inverse. Affecter leur niveau d'expression par surexpression ou inactivation n’a d’effet ni sur la teneur en Pi de la cellule végétale, ni sur des marqueurs classiques de la carence en Pi. Par contre, nous montrons que PS2;1 et PS2;2 assurent la dégradation de la phosphocholine et potentiellement la phosphoéthanolamine, deux composés identifiés comme substrats potentiels lors des analyses in vitro.Nos données ne suggèrent pas d’implication de PS2;1 et PS2;2 dans la dégradation du pyrophosphate, un troisième substrat potentiel proposé suites aux analyses in vitro. Nos résultats suggèrent que les deux protéines PS2;1 et PS2;2 interviennent in planta dans le remodelage des lipides membranaires déclenchés par la carence en Pi, permettant de convertir les phospholipides en galacto ou sulfolipides. Plus particulièrement, ces enzymes permettraient le recyclage du Pi des têtes polaires phosphocholine et phosphoéthanolamine, issues de la dégradation des phospholipides phosphatidylcholine et phosphatidyléthanolamine / Phosphate (Pi) is a macroelement essential to plant development. During Pi deficiency, the expression of several genes is deregulated, allowing the plant to cope with this type of abiotic stress. In Arabidopsis thaliana, Pi deficiency strongly induces PS2;1 (At1g73010) and PS2;2 (At1g17710), two HAD-type phosphatases. The biochemical functions of these two proteins were previously characterized in vitro, although their in vivo roles have not yet been established.Here, the functions of these two proteins were examined in plants using reverse genetics approaches. Overexpression or inactivation of their expression levels had no effect on the Pi content of the plant cell, or on classic markers of Pi deficiency. Furthermore, PS2;1 and PS2;2 affect phosphocholine levels in planta (and potentially phosphoethanolamine), two compounds identified as their potential substrates by in vitro assays.In contrast, these findings do not suggest any involvement of PS2;1 or PS2;2 in the degradation of pyrophosphate, another potential substrate according to previous in vitro assays. In conclusion, these results suggest that PS2;1 and PS2;2 are involved in the remodeling of membrane lipids triggered by Pi deficiency, allowing the conversion of phospholipids to galactolipids or sulfolipids. Specifically, these enzymes should allow the recycling of Pi from phosphocholine and phosphoethanolamine polar heads, byproducts of the degradation of phospholipid phosphatidylcholine and phosphatidylethanolamine Phosphate Arabidopsis Phosphatase Pyrophosphate Phosphocholine Phosphoéthanolamine Lipides membranaires Phosphate Arabidopsis Phosphatase Pyrophosphate Phosphocholine Phosphoethanolamine Membrane lipids 581
6	Structure-Function Relationships of C-Reactive Protein in Bacterial Infection Ngwa, Donald N., Agrawal, Alok 01 January 2019 (has links) This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms. One host defense function of C-reactive protein (CRP) is to protect against Streptococcus pneumoniae infection as shown by experiments employing murine models of pneumococcal infection. The protective effect of CRP is due to reduction in bacteremia. There is a distinct relationship between the structure of CRP and its anti-pneumococcal function. CRP is functional in both native and non-native pentameric structural conformations. In the native conformation, CRP binds to pneumococci through the phosphocholine molecules present on the C-polysaccharide of the pneumococcus and the anti-pneumococcal function probably involves the known ability of ligand-complexed CRP to activate the complement system. In the native structure-function relationship, CRP is protective only when given to mice within a few hours of the administration of pneumococci. The non-native pentameric conformation of CRP is created when CRP is exposed to conditions mimicking inflammatory microenvironments, such as acidic pH and redox conditions. In the non-native conformation, CRP binds to immobilized complement inhibitor factor H in addition to being able to bind to phosphocholine. Recent data using CRP mutants suggest that the factor H-binding function of non-native CRP is beneficial: in the non-native structure-function relationship, CRP can be given to mice any time after the administration of pneumococci irrespective of whether the pneumococci became complement-resistant or not. In conclusion, while native CRP is protective only against early stage infection, non-native CRP is protective against both early stage and late stage infections. Because non-native CRP displays phosphocholine-independent anti-pneumococcal activity, it is quite possible that CRP functions as a general anti-bacterial molecule. c-reactive protein factor H phosphocholine pneumococcal c-polysaccharide streptococcus pneumoniae Biomedical Sciences
7	Evolution of C-Reactive Protein Pathak, Asmita, Agrawal, Alok 01 January 2019 (has links) C-reactive protein (CRP) is an evolutionarily conserved protein. From arthropods to humans, CRP has been found in every organism where the presence of CRP has been sought. Human CRP is a pentamer made up of five identical subunits which binds to phosphocholine (PCh) in a Ca2+-dependent manner. In various species, we define a protein as CRP if it has any two of the following three characteristics: First, it is a cyclic oligomer of almost identical subunits of molecular weight 20–30 kDa. Second, it binds to PCh in a Ca2+-dependent manner. Third, it exhibits immunological cross-reactivity with human CRP. In the arthropod horseshoe crab, CRP is a constitutively expressed protein, while in humans, CRP is an acute phase plasma protein and a component of the acute phase response. As the nature of CRP gene expression evolved from a constitutively expressed protein in arthropods to an acute phase protein in humans, the definition of CRP became distinctive. In humans, CRP can be distinguished from other homologous proteins such as serum amyloid P, but this is not the case for most other vertebrates and invertebrates. Literature indicates that the binding ability of CRP to PCh is less relevant than its binding to other ligands. Human CRP displays structure-based ligand-binding specificities, but it is not known if that is true for invertebrate CRP. During evolution, changes in the intrachain disulfide and interchain disulfide bonds and changes in the glycosylation status of CRP may be responsible for different structure-function relationships of CRP in various species. More studies of invertebrate CRP are needed to understand the reasons behind such evolution of CRP. Also, CRP evolved as a component of and along with the development of the immune system. It is important to understand the biology of ancient CRP molecules because the knowledge could be useful for immunodeficient individuals. c-reactive protein pentraxin phosphocholine PTX3 serum amyloid P Biomedical Sciences
8	Conformationally Altered C-Reactive Protein Capable of Binding to Atherogenic Lipoproteins Reduces Atherosclerosis Pathak, Asmita, Singh, Sanjay K., Thewke, Douglas P., Agrawal, Alok 11 August 2020 (has links) The aim of this study was to test the hypothesis that C-reactive protein (CRP) protects against the development of atherosclerosis and that a conformational alteration of wild-type CRP is necessary for CRP to do so. Atherosclerosis is an inflammatory cardiovascular disease and CRP is a plasma protein produced by the liver in inflammatory states. The co-localization of CRP and low-density lipoproteins (LDL) at atherosclerotic lesions suggests a possible role of CRP in atherosclerosis. CRP binds to phosphocholine-containing molecules but does not interact with LDL unless the phosphocholine groups in LDL are exposed. However, CRP can bind to LDL, without the exposure of phosphocholine groups, if the native conformation of CRP is altered. Previously, we reported a CRP mutant, F66A/T76Y/E81A, generated by site-directed mutagenesis, that did not bind to phosphocholine. Unexpectedly, this mutant CRP, without any more conformational alteration, was found to bind to atherogenic LDL. We hypothesized that this CRP mutant, unlike wild-type CRP, could be anti-atherosclerotic and, accordingly, the effects of mutant CRP on atherosclerosis in atherosclerosis-prone LDL receptor-deficient mice were evaluated. Administration of mutant CRP into mice every other day for a few weeks slowed the progression of atherosclerosis. The size of atherosclerotic lesions in the aorta of mice treated with mutant CRP for 9 weeks was ~40% smaller than the lesions in the aorta of untreated mice. Thus, mutant CRP conferred protection against atherosclerosis, providing a proof of concept that a local inflammation-induced structural change in wild-type CRP is a prerequisite for CRP to control the development of atherosclerosis. atherosclerosis C-reactive protein inflammation low-density lipoprotein phosphocholine Biomedical Sciences
9	Phosphoethanolamine-Complexed C-Reactive Protein: A Pharmacological-Like Macromolecule That Binds to Native Low-Density Lipoprotein in Human Serum Singh, Sanjay, Suresh, Madathilparambil V., Prayther, Deborah C., Moorman, Jonathan P., Rusiñol, Antonio E., Agrawal, Alok 01 August 2008 (has links) Background: C-reactive protein (CRP) is an acute phase plasma protein. An important binding specificity of CRP is for the modified forms of low-density lipoprotein (LDL) in which the phosphocholine-binding sites of CRP participate. CRP, however, does not bind to native LDL. Methods: We investigated the interaction of CRP with native LDL using sucrose density gradient ultracentrifugation. Results: We found that the blocking of the phosphocholine-binding sites of CRP with phosphoethanolamine (PEt) converted CRP into a potent molecule for binding to native LDL. In the presence of PEt, CRP acquired the ability to bind to fluid-phase purified native LDL. Because purified native LDL may undergo subtle modifications, we also used whole human serum as the source of native LDL. In the presence of PEt, CRP bound to native LDL in serum also. The effect of PEt on CRP was selective for LDL because PEt-complexed CRP did not bind to high-density lipoprotein in the serum. Conclusions: The pharmacologic intervention of endogenous CRP by PEt-based compounds, or the use of exogenously prepared CRP-PEt complexes, may turn out to be an effective approach to capture native LDL cholesterol in vivo to prevent the development of atherosclerosis. C-reactive protein cholesterol low-density lipoprotein phosphocholine phosphoethanolamine Biomedical Sciences Internal Medicine
10	Mechanisms of the Anti-Pneumococcal Function of C-Reactive Protein Gang, Toh B 01 December 2013 (has links) (PDF) Human C-reactive protein (CRP) increases survival of and decreases bacteremia in mice infected with Streptococcus pneumoniae. Such protection of mice against pneumococcal infection is seen only when CRP is administered into mice 6 hours before to 2 hours after the injection of pneumococci, but not when CRP is given to mice at a later time. Our first aim was to define the mechanism of CRP-mediated initial protection of mice against infection. It was proposed that CRP binds to phosphocholine (PCh) moieties present in the cell wall and activates the complement system on the pneumococcal surface that kills the pathogen. We generated a CRP mutant F66A/T76Y/E81A incapable of binding to PCh. Mutant CRP did not protect mice from pneumococcal infection. Thus, the proposed hypothesis was correct; the PCh-binding property of CRP contributes to the protection of mice against pneumococcal infection. Our second aim was to investigate why CRP was not protective during the late stages of infection. Pneumococci are known to recruit an inhibitor of complement activation, factor H, from the host to their surface to escape complement attack. We considered the ability of CRP, in its nonnative form, to bind to factor H, and generated a CRP mutant E42Q/F66A/T76Y/E81A capable of binding to factor H. In vivo experiments using the quadruple CRP mutant are in progress. We anticipate that the combination of wild-type and quadruple mutant CRP should be protective during the late stages of infection; wild-type CRP would bind to PCh and activate complement while mutant CRP would cover factor H to prevent its complement-inhibitory activity. Our long-term goal is to explore the possibility of developing a CRP-based strategy to treat pneumococcal infection. C-reactive protein Phosphocholine phosphoethanolamine Factor H Complement Pneumococcal infection Biochemistry Immunology and Infectious Disease Molecular Biology

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