Alphavirus nonstructural protein 2 (nsP2) has pivotal roles in viral RNA replication, host cell shutoff, and inhibition of antiviral responses. Mutations that individually rendered other alphaviruses noncytopathic were introduced into chikungunya virus nsP2. Results show that (i) nsP2 mutation P718S only in combination with KR649AA or adaptive mutation D711G allowed noncytopathic replicon RNA replication, (ii) prohibiting nsP2 nuclear localization abrogates inhibition of antiviral interferon-induced JAK-STAT signaling, and (iii) nsP2 independently affects RNA replication, cytopathicity, and JAK-STAT signaling. Chikungunya virus (CHIKV) is a member of the Alphavirus genus within the Togaviridae family. In humans, infection by this mosquito-borne virus can result in the development of a high fever, rash, and incapacitating, sometimes chronic, arthralgia. In the last decade, CHIKV outbreaks occurred throughout the Indian Ocean region, including La Reunion, infecting up to onethird of the human population, before infecting millions of people in India and Southern Asia (1, 2). CHIKV is a positive-strand RNA virus that replicates in the cytoplasm of infected cells. The genome contains four nonstructural proteins (nsP1 to nsP4) that are directly translated from the genomic RNA (gRNA). The viral structural proteins are translated later in infection from subgenomic mRNA (sgRNA) (3).nsP1 is a methyltransferase and is associated with cellular membranes (4), nsP3 is a phosphoprotein that recruits host factor G3BP and consequently inhibits the formation of cellular stress granules (5, 6), and nsP4 is the viral RNA-dependent RNA polymerase (3). nsP2 contains the viral helicase, protease, and a putative C-terminal methyltransferase domain; associates with many host proteins; and can effectively shut down host cell protein synthesis (7-11). Alphavirus nsP2 also contains a nuclear localization signal (NLS) in its C-terminal domain (CHIKV nsP2 KR649-650) (Fig. 1A, top). nsP2 from related Semliki Forest virus (SFV) and Sindbis virus (SINV) has been shown to translocate to the nucleus (12-14), as specific mutations within the NLS retained SFV nsP2 in the cytoplasm and reduced its cytopathicity (15). In the nucleus, nsP2 of Old World alphaviruses (SFV, SINV, and CHIKV) has been reported to inhibit host cell mRNA transcription via degradation of a subunit of DNA-directed RNA polymerase II (RPB1) (16). Mutation of a conserved proline residue in a site homologous to CHIKV nsP2 P718 (Fig. 1A, bottom) rendered SINV noncytopathic and alleviated the transcriptional inhibition via RPB1 (16-18).In addition, alphavirus nsP2 has been shown to antagonize the host's main antiviral response, the interferon (IFN) response, in two ways: (i) beta interferon (IFN-) transcription via global host shutoff and (ii) downstream type I/II IFN-induced Janus kinase/ signal transducers and activators of transcription (JAK-STAT) signaling (16,(19)(20)(21)(22). Upon activation, phosphorylated STAT1/2 proteins translocate as dimers into the nucleus to activate t...
Most bacteria entering the bloodstream will be eliminated through complement activation on the bacterial surface and opsonophagocytosis. However, when these protective innate immune systems do not work optimally, or when bacteria are equipped with immune evasion mechanisms that prevent killing, this can lead to serious infections such as bacteremia and meningitis, which is associated with high morbidity and mortality. In order to study the complement evasion mechanisms of bacteria and the capacity of human blood to opsonize and kill bacteria, we developed a versatile whole blood killing assay wherein both phagocyte function and complement activity can easily be monitored and modulated. In this assay we use a selective thrombin inhibitor hirudin to fully preserve complement activity of whole blood. This assay allows controlled analysis of the requirements for active complement by replacing or heat-inactivating plasma, phagocyte function and bacterial immune evasion mechanisms that contribute to survival in human blood.
Streptococcus pneumoniae is a diverse species causing invasive as well as localized infections that result in massive global morbidity and mortality. Strains vary markedly in pathogenic potential, but the molecular basis is obscured by the diversity and plasticity of the pneumococcal genome. In the present study, S. pneumoniae serotype 3 blood (n ؍ 12) or ear (n ؍ 13) isolates were multilocus sequence typed (MLST) and assessed for biofilm formation and virulence phenotype. Blood and ear isolates exhibited similar MLST distributions but differed markedly in phenotype. Blood isolates formed robust biofilms only at pH 7.4, which were enhanced in Fe(III)-supplemented medium. Conversely, ear isolates formed biofilms only at pH 6.8, and Fe(III) was inhibitory. Biofilm formation paralleled luxS expression and genetic competence. In a mouse intranasal challenge model, blood isolates did not stably colonize the nasopharynx but spread to the blood; none spread to the ear. Ear isolates colonized the nasopharynx at higher levels and also spread to the ear compartment in a significant proportion of animals; none caused bacteremia. Thus, pneumococci of the same serotype and MLST exhibit distinct phenotypes in accordance with clinical site of isolation, indicative of stable niche adaptation within a clonal lineage.
Streptococcus pneumoniae is a major cause of life-threatening infections. Complement activation plays a vital role in opsonophagocytic killing of pneumococci in blood. Initial complement activation via the classical and lectin pathways is amplified through the alternative pathway amplification loop. Alternative pathway activity is inhibited by complement factor H (FH). Our study demonstrates the functional consequences of the variability in human serum FH levels on host defense. Using an in vivo mouse model combined with human in vitro assays, we show that the level of serum FH correlates with the efficacy of opsonophagocytic killing of pneumococci. In summary, we found that FH levels determine a delicate balance of alternative pathway activity, thus affecting the resistance to invasive pneumococcal disease. Our results suggest that variation in FH expression levels, naturally occurring in the human population, plays a thus far unrecognized role in the resistance to invasive pneumococcal disease.
The pneumococcal capsular serotype is an important determinant of complement resistance and invasive disease potential, but other virulence factors have also been found to contribute. Pneumococcal surface protein C (PspC), a highly variable virulence protein that binds complement factor H to evade C3 opsonization, is divided into two subgroups: choline-bound subgroup I and LPxTG-anchored subgroup II. The prevalence of different PspC subgroups in invasive pneumococcal disease (IPD) and functional differences in complement evasion are unknown. The prevalence of PspC subgroups in IPD isolates was determined in a collection of 349 sequenced strains of isolated from adult patients. deletion mutants and isogenic switch mutants were constructed to study differences in factor H binding and complement evasion in relation to capsule thickness. Subgroup I was far more prevalent in IPD isolates than subgroup II The presence of capsule was associated with a greater ability of bound factor H to reduce complement opsonization. Pneumococcal subgroup I PspC bound significantly more factor H and showed more effective complement evasion than subgroup II PspC in isogenic encapsulated pneumococci. We conclude that variation in the PspC subgroups, independent of capsule serotypes, affects pneumococcal factor H binding and its ability to evade complement deposition.
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