DNA based methods for serotype discrimination of Streptococcus pneumoniae

Lawrence, Elliot Roger

January 2001

No description available.

616

Pneumococcal infection

A molecular analysis of hyaluronate lyase production in Streptococcus pneumoniae

Doherty, Neil Christopher

January 2000

No description available.

572.8

Hyaluronidase; Pneumococcal infection

The role of pneumolysin in pro inflammatory mediator production

Search, Jennifer Julia

January 2002

No description available.

579

Pneumococcal infection

Impact d’une infection par le virus grippal de type A sur la myélopoïèse / Impact of influenza A virus infection on myelopoiesis

Beshara, Ranin

26 October 2018

L’infection par le virus de la grippe, ou le Myxovirus influenzae de type A (IAV), constitue l'une des causes les plus importantes de maladies des voies respiratoires dans le monde. Elle conduit également à des épidémies récurrentes avec des taux élevés de morbidité et de mortalité. Des surinfections bactériennes, principalement causées par Streptococcus pneumoniae (pneumonie), sont souvent associées à la grippe et contribuent de manière significative à l’excès de mortalité. La perturbation de l'intégrité des tissus pulmonaires et la diminution de l'immunité antibactérienne au cours de l'infection par IAV sont à l’origine de la colonisation et à la dissémination des bactéries.L'infection grippale entraîne une altération profonde du compartiment de cellules myéloïdes pulmonaires caractérisée par une altération numérique ou fonctionnelle des cellules sentinelles - les macrophages alvéolaires et les cellules dendritiques conventionnelles (cDC) - et par un recrutement de cellules myéloïdes inflammatoires -les neutrophiles, les monocytes inflammatoires ou encore les cellules dendritiques inflammatoires.Les cellules myéloïdes sont originaires de la moelle osseuse (MO). Lors d’infections, la myélopoïèse peut être profondément affectée afin de maintenir la production et la mobilisation de cellules myéloïdes inflammatoires au niveau du site d’infection. A l’heure actuelle, les conséquences de l’infection grippale sur la myélopoïèse restent encore mal connues.Dans notre projet, nous rapportons que l'infection grippale conduit à une diminution transitoire du nombre de cDC (cDC1 et cDC2) dans les poumons qui coïncide avec une chute dans la MO, du nombre de progéniteurs/précurseurs impliqués dans la génération des cDC (CDP, pre-cDC et plus particulièrement les pre-cDC1). Cette diminution de la "DCpoïèse" est associée à une accélération de la génération des monocytes, i.e. monopoïèse. La différenciation altérée des cDC est indépendante des cytokines pro-inflammatoires et n'est pas due à un dysfonctionnement intrinsèque des précurseurs de cDC. De façon intéressante, nous rapportons que ces altérations au niveau de la MO sont associées à une diminution de la production de Flt3-L ou Fms-like tyrosine kinase 3 ligand, un facteur crucial pour la différenciation des DC. La supplémentation en Flt3-L au cours de la grippe rétablit la différenciation des progéniteurs de cDC dans la MO et restaure le compartiment des cDC pulmonaires. De façon intéressante, cette restauration s’accompagne d’une protection partielle contre l’infection pneumococcique secondaire caractérisée par une réduction de la charge bactérienne, une amélioration de la pathologie pulmonaire et une survie prolongée. / Influenza type A virus (IAV) infection, is one of the most important causes of respiratory diseases worldwide. It also leads to recurrent epidemics with high rates of morbidity and mortality. Secondary bacterial infections, mainly caused by Streptococcus pneumoniae (pneumonia), are often associated with influenza and contribute significantly to excess mortality. Disruption of lung tissue integrity and impaired antibacterial immunity during IAV infection participate in bacterial pulmonary colonization and dissemination out of the lungs.Influenza infection leads to a profound alteration in the pulmonary myeloid cell compartment characterized by numeric or functional alteration of sentinel cells (alveolar macrophages and conventional dendritic cells (cDC)) and recruitment of inflammatory myeloid cells (neutrophils, inflammatory monocytes and inflammatory dendritic cells).Myeloid cells originate from the bone marrow (BM). During infections, myelopoiesis may be profoundly affected in order to maintain the production and mobilization of inflammatory myeloid cells to the site of infection. At present, the consequences of influenza infection on myelopoiesis remain poorly understood.In our project, we report that influenza infection leads to a transient decrease in the number of Cdc (cDC1 and cDC2) in the lungs, and severely impairs the number of BM progenitors committed to the DC lineage (CDP, pre-cDC and, most importantly, the cDC1-biased pre-DC lineage). This reduction was associated with an increase in the production of monocytes in the BM (monopoiesis). The altered cDC differentiation was independent of pro-inflammatory cytokines and was not due to an intrinsic dysfunction of cDC precursors. Defective DC genesis during influenza was associated with a decrease in the production of the key cDC differentiation factor, Fms-like tyrosine kinase 3 ligand (Flt3-L). Importantly, Flt3-L overexpression during influenza restores the differentiation of BM progenitors into cDC - a phenomenon associated with repopulation of cDC in the lungs. The restoration of pulmonary cDC associates with a partial protection against secondary pneumococcal infection characterized by reduced bacterial loads, improved pathological outcomes and prolonged survival.

Infection grippale

DCpoïèse

Monopoïèse FLt3-L

Infection bactérienne secondaire

Influenza infection

Myelopoiesis

Secondary pneumococcal infection

C-Reactive Protein-Based Strategy to Reduce Antibiotic Dosing for the Treatment of Pneumococcal Infection

Ngwa, Donald N., Singh, Sanjay K., Agrawal, Alok

20 January 2021

C-reactive protein (CRP) is a component of innate immunity. The concentration of CRP in serum increases in microbial infections including Streptococcus pneumoniae infection. Employing a mouse model of pneumococcal infection, it has been shown that passively administered human wild-type CRP protects mice against infection, provided that CRP is injected into mice within two hours of administering pneumococci. Engineered CRP (E-CRP) molecules have been reported recently; unlike wild-type CRP, passively administered E-CRP protected mice against infection even when E-CRP was injected into mice after twelve hours of administering pneumococci. The current study was aimed at comparing the protective capacity of E-CRP with that of an antibiotic clarithromycin. We established a mouse model of pneumococcal infection in which both E-CRP and clarithromycin, when used alone, provided minimal but equal protection against infection. In this model, the combination of E-CRP and clarithromycin drastically reduced bacteremia and increased survival of mice when compared to the protective effects of either E-CRP or clarithromycin alone. E-CRP was more effective in reducing bacteremia in mice treated with clarithromycin than in untreated mice. Also, there was 90% reduction in antibiotic dosing by including E-CRP in the antibiotic-treatment for maximal protection of infected mice. These findings provide an example of cooperation between the innate immune system and molecules that prevent multiplication of bacteria, and that should be exploited to develop novel combination therapies for infections against multidrug-resistant pneumococci. The reduction in antibiotic dosing by including E-CRP in the combination therapy might also resolve the problem of developing antibiotic resistance.

c-reactive protein

clarithromycin

combination therapy

pneumococcal infection

streptococcus pneumoniae

Biomedical Sciences

Treatment of Pneumococcal Infection by Using Engineered Human C-Reactive Protein in a Mouse Model

Ngwa, Donald N., Singh, Sanjay K., Gang, Toh B., Agrawal, Alok

07 October 2020

C-reactive protein (CRP) binds to several species of bacterial pathogens including Streptococcus pneumoniae. Experiments in mice have revealed that one of the functions of CRP is to protect against pneumococcal infection by binding to pneumococci and activating the complement system. For protection, however, CRP must be injected into mice within a few hours of administering pneumococci, that is, CRP is protective against early-stage infection but not against late-stage infection. It is assumed that CRP cannot protect if pneumococci got time to recruit complement inhibitor factor H on their surface to become complement attack-resistant. Since the conformation of CRP is altered under inflammatory conditions and altered CRP binds to immobilized factor H also, we hypothesized that in order to protect against late-stage infection, CRP needed to change its structure and that was not happening in mice. Accordingly, we engineered CRP molecules (E-CRP) which bind to factor H on pneumococci but do not bind to factor H on any host cell in the blood. We found that E-CRP, in cooperation with wild-type CRP, was protective regardless of the timing of administering E-CRP into mice. We conclude that CRP acts via two different conformations to execute its anti-pneumococcal function and a model for the mechanism of action of CRP is proposed. These results suggest that pre-modified CRP, such as E-CRP, is therapeutically beneficial to decrease bacteremia in pneumococcal infection. Our findings may also have implications for infections with antibiotic-resistant pneumococcal strains and for infections with other bacterial species that use host proteins to evade complement-mediated killing.

C-reactive protein

complement

factor H

pneumococcal infection

Streptococcus pneumoniae

Biomedical Sciences

Complement Activation by C-Reactive Protein Is Critical for Protection of Mice Against Pneumococcal Infection

Singh, Sanjay K., Ngwa, Donald N., Agrawal, Alok

13 August 2020

C-reactive protein (CRP), a component of the innate immune system, is an antipneumococcal plasma protein. Human CRP has been shown to protect mice against infection with lethal doses of Streptococcus pneumoniae by decreasing bacteremia. in vitro, CRP binds to phosphocholine-containing substances, such as pneumococcal C-polysaccharide, in a Ca2+-dependent manner. Phosphocholine-complexed human CRP activates the complement system in both human and murine sera. The mechanism of antipneumococcal action of CRP in vivo, however, has not been defined yet. In this study, we tested a decades-old hypothesis that the complement-activating property of phosphocholine-complexed CRP contributes to protection of mice against pneumococcal infection. Our approach was to investigate a CRP mutant, incapable of activating murine complement, in mouse protection experiments. We employed site-directed mutagenesis of CRP, guided by its three-dimensional structure, and identified a mutant H38R which, unlike wild-type CRP, did not activate complement in murine serum. Substitution of His38 with Arg in CRP did not affect the pentameric structure of CRP, did not affect the binding of CRP to pneumococci, and did not decrease the stability of CRP in mouse circulation. Employing a murine model of pneumococcal infection, we found that passively administered H38R CRP failed to protect mice against infection. Infected mice injected with H38R CRP showed no reduction in bacteremia and did not survive longer, as opposed to infected mice treated with wild-type CRP. Thus, the hypothesis that complement activation by phosphocholine-complexed CRP is an antipneumococcal effector function was supported. We can conclude now that complement activation by phosphocholine-complexed CRP is indeed essential for CRP-mediated protection of mice against pneumococcal infection.

acute phase response

C-reactive protein

complement

inflammation

pneumococcal infection

Biomedical Sciences

Mechanisms of the Anti-Pneumococcal Function of C-Reactive Protein

Gang, Toh B

01 December 2013

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

Expression And Function Of Human IkappaBzeta In Lung Inflammation

Sundaram, Kruthika

08 October 2015

No description available.

Immunology