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Life-threatening toxic shock syndrome is often caused by the superantigen toxic shock syndrome toxin-1 (TSST-1) produced by Staphylococcus aureus. A well-known risk factor is the lack of neutralizing antibodies. To identify determinants of the anti-TSST-1 antibody response, we examined 976 participants of the German population-based epidemiological Study of Health in Pomerania (SHIP-TREND-0). We measured anti-TSST-1 antibody levels, analyzed the colonization with TSST-1-encoding S. aureus strains, and performed a genome-wide association analysis of genetic risk factors. TSST-1-specific serum IgG levels varied over a range of 4.2 logs and were elevated by a factor of 12.3 upon nasal colonization with TSST-1-encoding S. aureus. Moreover, the anti-TSST-1 antibody levels were strongly associated with HLA class II gene loci. HLA-DRB1*03:01 and HLA-DQB1*02:01 were positively, and HLA-DRB1*01:01 as well as HLA-DQB1*05:01 negatively associated with the anti-TSST-1 antibody levels. Thus, both toxin exposure and HLA alleles affect the human antibody response to TSST-1.
BCL11B, an essential transcription factor for thymopoiesis, regulates also vital processes in post-thymic lymphocytes. Increased expression of BCL11B was recently correlated with the maturation of NK cells, whereas reduced BCL11B levels were observed in native and induced T cell subsets displaying NK cell features. We show that BCL11B-depleted CD8+ T cells stimulated with IL-15 acquired remarkable innate characteristics. These induced innate CD8+ (iiT8) cells expressed multiple innate receptors like NKp30, CD161, and CD16 as well as factors regulating migration and tissue homing while maintaining their T cell phenotype. The iiT8 cells effectively killed leukemic cells spontaneously and neuroblastoma spheroids in the presence of a tumor-specific monoclonal antibody mediated by CD16 receptor activation. These iiT8 cells integrate the innate natural killer cell activity with adaptive T cell longevity, promising an interesting therapeutic potential. Our study demonstrates that innate T cells, albeit of limited clinical applicability given their low frequency, can be efficiently generated from peripheral blood and applied for adoptive transfer, CAR therapy, or combined with therapeutic antibodies.
Impact of different oral treatments on the composition of the supragingival plaque microbiome
(2022)
Background
Antiseptics are used to inhibit oral biofilm growth. However, they affect not only pathogenic but also commensal bacteria, which are a natural barrier against oral diseases.
Objective
Using a metaproteome approach combined with a standard plaque-regrowth study, this pilot study examined the impact of different concentrations of lactoperoxidase (LPO)-system containing lozenges on early plaque formation, and active biological processes.
Design
Sixteen orally healthy subjects received four local treatments as a randomized single-blind study based on a cross-over design. Two lozenges containing components of the LPO-system in different concentrations were compared to a placebo and Listerine®. The newly formed dental plaque was analyzed by mass spectrometry (nLC-MS/MS).
Results
On average 1,916 metaproteins per sample were identified, which could be assigned to 116 genera and 1,316 protein functions. Listerine® reduced the number of metaprotein groups and their relative abundance, confirming the plaque inhibiting effect. The LPO-lozenges triggered mainly higher metaprotein abundances of early and secondary colonizers as well as bacteria associated with dental health but also periodontitis. Functional information indicated plaque biofilm growth.
Conclusion
The effects of Listerine® and LPO-system containing lozenges used for plaque inhibition are different. In contrast to Listerine®, the lozenges allowed maintenance of a higher bacterial diversity.
Vector-based SARS-CoV-2 vaccines have been associated with vaccine- induced thrombosis with thrombocytopenia syndrome (VITT/TTS), but the causative factors are still unresolved. We comprehensively analyzed the ChAdOx1 nCoV-19 (AstraZeneca) and Ad26.COV2.S (Johnson and Johnson) vaccines. ChAdOx1 nCoV-19 contains significant amounts of host cell protein impurities, including functionally active proteasomes, and adenoviral proteins. A much smaller amount of impurities was found in Ad26.COV2.S. Platelet factor 4 formed complexes with ChAdOx1 nCoV-19 constituents, but not with purified virions from ChAdOx1 nCoV-19 or with Ad26.COV2.S. Vascular hyperpermeability was induced by ChAdOx nCoV-19 but not by Ad26.COV2.S. These differences in impurities together with EDTAinduced capillary leakage might contribute to the higher incidence rate of VITT associated with ChAdOx1 nCoV-19 compared to Ad26.COV2.S.
Our goal was to provide a comprehensive overview of the antibody response to Staphylococcus aureus antigens in the general population as a basis for defining disease-specific profiles and diagnostic signatures. We tested the specific IgG and IgA responses to 79 staphylococcal antigens in 996 individuals from the population-based Study of Health in Pomerania. Using a dilution-based multiplex suspension array, we extended the dynamic range of specific antibody detection to seven orders of magnitude, allowing the precise quantification of high and low abundant antibody specificities in the same sample. The observed IgG and IgA antibody responses were highly heterogeneous with differences between individuals as well as between bacterial antigens that spanned several orders of magnitude. Some antigens elicited significantly more IgG than IgA and vice versa. We confirmed a strong influence of colonization on the antibody response and quantified the influence of sex, smoking, age, body mass index, and serum glucose on anti-staphylococcal IgG and IgA. However, all host parameters tested explain only a small part of the extensive variability in individual response to the different antigens of S. aureus.
Abstract
Proteome analyses are often hampered by the low amount of available starting material like a low bacterial cell number obtained from in vivo settings. Here, the single pot solid‐phase enhanced sample preparation (SP3) protocol is adapted and combined with effective cell disruption using detergents for the proteome analysis of bacteria available in limited numbers only. Using this optimized protocol, identification of peptides and proteins for different Gram‐positive and Gram‐negative species can be dramatically increased and, reliable quantification can also be ensured. This adapted method is compared to already established strain‐specific sample processing protocols for Staphylococcus aureus, Streptococcus suis, and Legionella pneumophila. The highest species‐specific increase in identifications is observed using the adapted method with L. pneumophila samples by increasing protein and peptide identifications up to 300% and 620%, respectively. This increase is accompanied by an improvement in reproducibility of protein quantification and data completeness between replicates. Thus, this protocol is of interest for performing comprehensive proteomics analyses of low bacterial cell numbers from different settings ranging from infection assays to environmental samples.
Intranasal Vaccination With Lipoproteins Confers Protection Against Pneumococcal Colonisation
(2018)
Streptococcus pneumoniae is endowed with a variety of surface-exposed proteins representing putative vaccine candidates. Lipoproteins are covalently anchored to the cell membrane and highly conserved among pneumococcal serotypes. Here, we evaluated these lipoproteins for their immunogenicity and protective potential against pneumococcal colonisation. A multiplex-based immunoproteomics approach revealed the immunogenicity of selected lipoproteins. High antibody titres were measured in sera from mice immunised with the lipoproteins MetQ, PnrA, PsaA, and DacB. An analysis of convalescent patient sera confirmed the immunogenicity of these lipoproteins. Examining the surface localisation and accessibility of the lipoproteins using flow cytometry indicated that PnrA and DacB were highly abundant on the surface of the bacteria. Mice were immunised intranasally with PnrA, DacB, and MetQ using cholera toxin subunit B (CTB) as an adjuvant, followed by an intranasal challenge with S. pneumoniae D39. PnrA protected the mice from pneumococcal colonisation. For the immunisation with DacB and MetQ, a trend in reducing the bacterial load could be observed, although this effect was not statistically significant. The reduction in bacterial colonisation was correlated with the increased production of antigen-specific IL-17A in the nasal cavity. Immunisation induced high systemic IgG levels with a predominance for the IgG1 isotype, except for DacB, where IgG levels were substantially lower compared to MetQ and PnrA. Our results indicate that lipoproteins are interesting targets for future vaccine strategies as they are highly conserved, abundant, and immunogenic.
Whether mice are an appropriate model for S. aureus infection and vaccination studies is a matter of debate, because they are not considered as natural hosts of S. aureus. We previously identified a mouse-adapted S. aureus strain, which caused infections in laboratory mice. This raised the question whether laboratory mice are commonly colonized with S. aureus and whether this might impact on infection experiments. Publicly available health reports from commercial vendors revealed that S. aureus colonization is rather frequent, with rates as high as 21% among specific-pathogen-free mice. In animal facilities, S. aureus was readily transmitted from parents to offspring, which became persistently colonized. Among 99 murine S. aureus isolates from Charles River Laboratories half belonged to the lineage CC88 (54.5%), followed by CC15, CC5, CC188, and CC8. A comparison of human and murine S. aureus isolates revealed features of host adaptation. In detail, murine strains lacked hlb-converting phages and superantigen-encoding mobile genetic elements, and were frequently ampicillin-sensitive. Moreover, murine CC88 isolates coagulated mouse plasma faster than human CC88 isolates. Importantly, S. aureus colonization clearly primed the murine immune system, inducing a systemic IgG response specific for numerous S. aureus proteins, including several vaccine candidates. Phospholipase C emerged as a promising test antigen for monitoring S. aureus colonization in laboratory mice. In conclusion, laboratory mice are natural hosts of S. aureus and therefore, could provide better infection models than previously assumed. Pre-exposure to the bacteria is a possible confounder in S. aureus infection and vaccination studies and should be monitored.
Staphylococcus aureus is a human pathogen that can cause a wide range of diseases. Although formerly regarded as extracellular pathogen, it has been shown that S. aureus can also be internalized by host cells and persist within these cells. In the present study, we comparatively analyzed survival and physiological adaptation of S. aureus HG001 after internalization by two human lung epithelial cell lines (S9 and A549), and human embryonic kidney cells (HEK 293). Combining enrichment of bacteria from host-pathogen assays by cell sorting and quantitation of the pathogen's proteome by mass spectrometry we characterized S. aureus adaptation during the initial phase between 2.5 h and 6.5 h post-infection. Starting with about 2 × 106 bacteria, roughly 1450 S. aureus proteins, including virulence factors and metabolic enzymes were identified by spectral comparison and classical database searches. Most of the bacterial adaptation reactions, such as decreased levels of ribosomal proteins and metabolic enzymes or increased amounts of proteins involved in arginine and lysine biosynthesis, enzymes coding for terminal oxidases and stress responsive proteins or activation of the sigma factor SigB were observed after internalization into any of the three cell lines studied. However, differences were noted in central carbon metabolism including regulation of fermentation and threonine degradation. Since these differences coincided with different intracellular growth behavior, complementary profiling of the metabolome of the different non-infected host cell types was performed. This revealed similar levels of intracellular glucose but host cell specific differences in the amounts of amino acids such as glycine, threonine or glutamate. With this comparative study we provide an impression of the common and specific features of the adaptation of S. aureus HG001 to specific host cell environments as a starting point for follow-up studies with different strain isolates and regulatory mutants.
Proteolysis represents the final step in the life of a protein. It is one of the most important cellular processes assisted by chaperone systems and ensures an appropriate protein homeostasis. Protein degradation is essential for the removal of cytotoxic protein aggregates and mis-translated/mal-folded proteins, „unemployed“ and regulatory proteins to enable rapid cell adaptation to altering environmental conditions (Gottesman, 2003; Wiegert & Schumann, 2001; Parker, 1981; Stansfield et al., 1998; Drummond & Wilke, 2008; Goldberg, 1972; Gerth et al., 2008). The bacterial Clp (caseinolytic proteins) protease complexes are analogous to the eukaryotic 26S proteasome and consist of Hsp100/Clp proteins of the AAA+ superfamily and an associated barrel-like proteolytic chamber (e.g. ClpP). The Clp proteases seem to be responsible for the major protein turnover in low GC, Gram+ bacteria. The main goal of this thesis was to develop new methods and tools to investigate global proteolysis more precisely and to get a detailed understanding of protein degradation during starvation conditions and it´s regulation in low GC, Gram-positive bacteria. To analyse protein degradation under starvation conditions the well established glucose starvation model was used. In Bacillus subtilis it could be shown that approximately 200 proteins are selectively degraded in a glucose depletion induced stationary phase. Furthermore radioactive pulse-chase labelling experiments coupled with 2D-PAGE analysis revealed that mainly the ClpCP protease complex is involved in the degradation of proteins in the stationary growth phase. To investigate proteolysis in the human pathogen Staphylococcus aureus in the same way, a newly developed chemically defined medium was established suitable for radioactive pulse-chase labelling experiments under stable glucose starvation conditions. The degradation kinetics of individual 2D spots was significantly better resolved using 14C-BSA as an internal marker protein for the sample normalisation. A rather huge overlap was found within the functional protein classes that were degraded in B. subtilis and S. aureus the stationary phase. Among others, especially proteins involved in amino acid, nucleotide and cell wall biosynthesis were rapidly degraded, whereby not always the same and sometimes another enzymes from a biosynthetic chain were targeted for proteolysis. Despite the resolution power of the 2D-PAGE method, there are some drawbacks such as a limited "protein window" with regard to the molecular weight and isoelectric point, loss of low abundance proteins and a rather low reproducibility for time course experiments. Therefore a mass spectrometry based approach for the simultaneous detection of protein synthesis, accumulation and degradation was developed. This pulse-chase SILAC approach provides a very good reliability with a broad spectrum of proteins that can be analysed. Through the combination with ultracentrifugation even non-soluble and aggregated proteins could be analysed. Several hundred proteins were degraded in S. aureus during glucose starvation. Among them was the functional cluster of ribosomal proteins which is degraded in the early stationary phase. Furthermore proteins belonging to complexes were degraded with the same kinetic (e.g. NrdE, NrdF). In addition selective protein degradation took place according to functional categories (e.g., ribosomal proteins, biosynthetic, glycolytic enzymes) and not to regulatory groups (e.g. CcpA, SigB regulon).The investigation of a clpP deletion mutant in S. aureus revealed a greater susceptibility to aggregation, where the cells try to counteract with the expression of chaperones like GroEL/ES, ClpB and DnaK. The renaturation process is very ATP consuming and only takes place in energy rich phases of growth (e.g. from exponential to transient growth phase). Protein aggregation was found enhanced in the stationary phase. Furthermore, a higher GTP level compared to the wild-type probably resulted in a stronger CodY mediated repression with a rather low level of amino acids in clpP mutant cell. In addition substances like glycerol, which thermodynamically stabilise proteins in refolding processes (Maeda et al., 1996; Feng & Yan, 2008), were found in higher levels compared to the wild-type. A strong response to reactive oxygen species was detected in the clpP mutant strain, which is probably due to ROS production during the early stages of protein aggregation. Altogether, different methods were used for investigation protein degradation at a proteome-wide scale. Hundreds of degradation candidates were identified by gel-based and gel-free approaches in S. aureus wild-type cells. “Unemployed” proteins (e.g. ribosomal proteins, biosynthetic enzymes) were degraded and proteins particularly required and synthesized in glucose-starved cells such as TCA cycle enzymes were stable in the stationary phase. Investigation of the clpP mutant strain supports a proposed model for the pleiotropic phenotype and provides a deeper insight in the fine-tuned protein quality control and the important role of ClpP during starving conditions.