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Streptococcus pneumoniae (the pneumococcus) is an opportunistic human pathogen that causes life-threatening diseases including pneumonia, sepsis, meningitis but also non-invasive local infections such as otitis media. Pneumococci have evolved versatile strategies to colonize the upper respiratory tract (URT) of humans. Binding to epithelial surfaces is thereby mediated through direct interactions with host cell receptors or indirectly via binding to components of the extracellular matrix (ECM). However, successful colonization and subsequent infection require S. pneumoniae to cross tissue barriers protected by the immune system of the host. Pneumococci have therefore evolved a wide range of mechanisms to circumvent the antibacterial activity of the immune system such as the acquisition or expression of serine protease activity. Serine protease enzymes have emerged during evolution as one of the most abundant and functionally diverse groups of proteins in eukaryotic and prokaryotic organisms. However, the epithelial barriers, integrins, and other cell surface receptors are often initially inaccessible for pneumococci colonizing the nasopharyngeal cavity. Therefore, pneumococci recruit host-derived extracellular serine proteases such as plasmin(ogen) for extracellular matrix and mucus degradation, which results in enhanced binding to epithelial and endothelial cells. S. pneumoniae expresses four surface-anchored or surface-associated serine proteases depending on the serotype: HtrA, SFP, PrtA, and CbpG. These enzymes belong to the category of trypsin-like or subtilisin-like family proteins, which are characterized by the presence of three-conserved amino acid residues, Ser-His-Asp. The catalytic triads are critical for the cleavage of peptide bonds. Studies focusing on the deletion of single pneumococcal serine proteases are difficult to interpret due to the compensatory effects of the other serine proteases.
Initially, a comprehensive in silico analysis of the distribution and genes organization of pneumococcal serine proteases was carried out in this study. Interestingly, the genes encoding PrtA, HtrA, and CbpG were highly conserved among the 11 analyzed strains. Surprisingly, the gene encoding the subtilisin-like protein SFP was not present in some of the strains and seems to be strain-dependent. Therefore, pneumococci have at least three serine proteases as shown e.g., for serotype 19F_EF3030 strain. Computer-assisted analyses of the structure of pneumococcal serine proteases showed high similarities in the catalytic domains between HtrA and CbpG or between PrtA and SFP in 3D structural models.
The focus of this study lies on the impact of single extracellular pneumococcal serine proteases on pneumococcal pathogenesis during adherence, colonization, virulence and biofilm formation. Therefore, double and triple deletion mutants were generated in the colonizing S. pneumoniae serotype 19F strain EF3030 and the more invasive serotype 4 strain TIGR4, respectively. In adherence studies with human Detroit-562 epithelial cells, we demonstrated that both TIGR4Δcps and 19F_EF3030 mutants without serine proteases or expressing only CbpG, HtrA, or PrtA have a reduced ability to adhere to Detroit-562 cells. In a mouse colonization model, the inactivation of serine proteases in strain 19F_EF3030 strongly reduced nasopharyngeal colonization in CD-1 mice. The bacterial load in the nasopharynx was thereby monitored for a period of 14 days. Mutant strains showed significantly lower bacterial numbers in the nasopharynx on days 2, 3, 7, and 14 post-inoculations.
Following up on pneumococcal pathogenesis, an in vivo acute pneumonia mouse infection model and in vitro phagocytosis was used to analyze the impact of single serine proteases during infection and phagocytosis. Mice were intranasally infected with the bioluminescent TIGR4lux wild-type or isogenic triple mutants expressing only CbpG, HtrA, PrtA, or SFP. The acute lung infection was monitored in real-time by using an IVIS®-Spectrum in vivo imaging system. The TIGR4lux mutant expressing only PrtA showed a significant attenuation and was less virulent in the acute pneumonia model. Phagocytosis assays were conducted using murine J77A.1 macrophages. The number of triple serine protease mutants internalized by macrophages were significantly reduced in comparison to the isogenic wild-type.
Finally, two different experimental biofilm models were used to study the influence of serine proteases on biofilm formation grown on an abiotic surface (glass) and a biological surface. Biofilm development on living epithelial cells was stronger after 48 and 72h than on the glass surface. On epithelial substratum, the serine protease mutant with only CbpG+ showed higher and denser biofilm development after 48h and 72h of incubation compared to the parental strains and other serine protease mutants. Moreover, the bacterial dispersal from biofilms was significantly more in the mutant strains lacking serine proteases than in the wild type.
In conclusion, nasopharyngeal colonization is a prerequisite for invasive diseases and transmission. Pneumococcal serine proteases are indispensable for nasopharyngeal colonization and facilitate access to eukaryotic cell-surface receptors by the cleavage of ECM proteins. Thus, serine proteases could be promising candidates for developing antimicrobials to reduce pneumococcal colonization and transmission.
The human innate response plays a pivotal role in detection of pathogen- or damage-associated molecular patterns (PAMPs and DAMPs) and contributes to a crucial inflammatory response. PAMPs or DAMPs are recognized by the host immune system via pattern recognition receptors (PRRs). NLR family pyrin domain-containing 3 (NLRP3) inflammasome is one of these PRRs. NLRP3 is a cytoplasmic immune sensor that upon activation produce pro-inflammatory cytokines such as IL-1β and IL-18. These cytokines induce a diverse range of protective host pathways aiming to eradicate the pathogen. However, excessive or chronic inflammasome activation are implicated in the pathogenesis of several autoimmune and auto-inflammatory disorders. Pharmacologic inhibitors of IL-1 are commonly used to combat these disorders. In paper I, we explore the currently available IL-1β inhibiting therapies and how patients undergoing these treatments are at a disproportionate risk to experience invasive bacterial infections. We also summarize the limited knowledge on the role of NLRP3 inflammasome in pneumococcal pathogenesis.
Hydrogen peroxide (H2O2) is a physiological metabolite and an important virulence determinant produced by pneumococci. It is highly cytotoxic to host cells. However, not much is known about its impact on host cell death pathways such as NLRP3 inflammasome mediated pyroptosis. In Paper II, we examined the effect of pneumococci-derived H2O2 on epithelial cells by analyzing the interplay between two key cell death pathways, namely apoptosis and pyroptosis. We show that H2O2 can prime as well as activate the NLRP3 inflammasome. Furthermore, we demonstrate that pneumococcal H2O2 initiates cell death via the activation of both apoptotic as well as pyroptotic pathways, mediated by the activation of caspase-3/7 and caspase-1, respectively. H2O2 mediated inflammasome activation results in caspase-1 dependent IL 1β production. However, we show that the final IL-1β release is independent of gasdermin-D (GSDMD) and mainly dependent on the apoptotic cell lysis.
In paper III, we focused on understanding the host metabolic responses to infections with pathogens which cause respiratory diseases. We performed metabolome profiling of in vitro single bacterial and viral as well as co-infections of bronchial epithelial cells with Influenza A virus (IAV), Streptococcus pneumoniae, and Staphylococcus aureus. We show that IAV and S. aureus use the host resources for survival and multiplication and have minimal effects on the host metabolome. In contrast, pneumococci significantly alter various host metabolome pathways, including glycolysis, tricarboxylic acid (TCA) cycle and amino-acid metabolism. A hallmark of pneumococcal infections was the intracellular citrate accumulation, which was directly attributed to the action of pneumococci-derived H2O2.
Host cell death during an infection results in the release of pro-inflammatory cytokines and danger signals such as ATP. Released ATP can induce neutrophil chemotaxis mediated via purinergic signaling. Neutrophils are typically the first leukocytes to be recruited to the site of infection and are key players in bacterial clearance. However, excessive neutrophil activation is associated with further tissue injury. In paper IV, we investigated the role of ATP in neutrophil response to pneumococcal infections. We show that pneumolysin (Ply), a highly effective pore-forming toxin produced by pneumococci, is a potent activator of neutrophils. Microscale Thermophoresis analysis revealed that Ply and ATP bind to each other. Subsequently, ATP binding neutralizes Ply-mediated neutrophil degranulation, suggesting that Ply-ATP interactions are potentially beneficial during the course of the infection as this could limit the lung injury resulting from excessive Ply-mediated neutrophil activation.
Summary
Streptococcus pneumoniae (the pneumococcus), a bacterium belonging to the normal flora in the human respiratory tract, continues to be an important pathogen due to its contribution to morbidity and mortality among children, the elderly, and immunocompromised persons. Global estimates of pneumococcal deaths among children declined by 51% between 2000 and 2015. This achievement was mainly due to the introduction of pneumococcal conjugate vaccines (PCVs) in countries with the highest pneumococcal burden. Since May 2012, children in Ghana have been receiving PCV vaccination as part of routine immunization. The continuous monitoring of the pneumococcus after PCV introduction is essential to understand the changing epidemiology of the pathogen in the population.
This study therefore, aims to determine the (1) prevalence, serotypes, and sequence types of pneumococcal isolates, (2) antibiotic susceptibility patterns and the genetic basis for the antibiotic resistance among these pneumococcal isolates, and (3) prevalence of selected virulence genes that have been identified as potential vaccine candidates. Nasopharyngeal swabs were obtained from vaccinated children under five years of age in Cape Coast, Ghana. Six years after PCV implementation, we provide data on the epidemiology of pneumococcal strains circulating among children in Cape Coast Ghana. Standard microbiological and molecular techniques were used to identify and characterize the pneumococcal strains.
Overall, pneumococcal carriage prevalence was 29.4% (151/513). All participating children were fully vaccinated. Of the 26 different serotypes identified, the top five PCV13 serotypes (VT) were 6B, 23F, 19F, 3, 6A and non-PCV13 vaccine serotypes (NVT) were 23B, 13, 11A, 15B, and 34. PCV13 coverage was 38.4%, however, more than half of the isolates were NVT with a coverage rate of 61.6%. The isolates were highly susceptible to levofloxacin, ceftriaxone, vancomycin, and erythromycin. However, marked resistance to cotrimoxazole and tetracycline was observed. The reduction in penicillin resistance (35.8%) as compared to pre-vaccination data (45% - 63%) suggests an attributable effect from PCV13 vaccination. However, penicillin resistance was also detected in some NVT serotypes. Overall, 28.5% of the isolates resistant to three or more different classes of antibiotics were classified as multidrug-resistant (MDR). To analyze the genetic basis for resistance to penicillin, erythromycin and tetracycline, pbp2b, ermB, mefA, and tetM genes were amplified.
Thirty-eight (70%) out of the 54 penicillin-resistant isolates contained the pbp2b resistance gene. Out of the 11 erythromycin-resistant isolates, 7 (63.6) and 4 (36.4%) were positive for the ermB and mefA genes, respectively. The tetM gene was detected in 85 (98.8%) of the 86 tetracycline resistance isolates.
To determine the extent to which potential protein-based vaccines could be protective in Ghanaian children, we sought to determine the prevalence of selected virulence genes among the isolates. The lytA, pavB, and cpsA genes were present in all the carrier isolates. However, psrP, pcpA, pilus islet (PI) PI-1, and PI-2 were present in 62.7%, 87.5%, 11.8%, and 6.5% of the strains, respectively. The psrP and pcpA virulence genes were evenly distributed among all the serotypes. However, the pilus islets were detected in only seven serotypes namely 19F, 6B, 9V, 6A, 13, 11A, and 23B. Five serotype 19F isolates possessed both PI-1 and PI-2. Furthermore, the pilus islets were associated with multidrug resistance.
The predominant NVT serotype 23B and isolates resistant to ≥ 4 antibiotics were analysed by multilocus sequence typing (MLST). Nine known sequence types (STs) and 10 novel STs were identified. Seven out of the 10 new STs belonged to serotype 23B, while the remaining 3 were VTs 6B and 19F. A capsular switch was identified among isolates of ST802, which comprised of both serotype 23F and 19F. The majority of serotype 23B strains belonged to ST172. The ST172 is associated with serotype 23F and a single locus variant (SLV) of internationally disseminated clone ST338 (Colombia23F-26). Consequently, ST172 was characterised with marked antibiotic resistance and with traits of capsular switching. One serotype 6B strain was identified as a SLV of ST273 (Greece6B-22) while two serotype 9V strains belonged to the internationally disseminated clone ST156 (Spain9V-3).
In conclusion, this study showed a marginal decline in overall pneumococcal carriage prevalence, persistence of VTs despite the increase in NVTs, and the occurrence of serotype replacement and capsular switching. In addition, sequence types related to internationally disseminated clones are circulating in Ghana. With the high pcpA and psrP coverage detected,including these genes in protein-based vaccines could provide adequate protection for Ghanaian Children.
Streptococcus pneumoniae is a commensal of the human upper respiratory tract and
the etiological agent of several life-threatening diseases. This pathogen is the model bacterium
for natural competence. Furthermore, the pneumococci played an important role in the
identification of DNA as the main molecule involved in bacterial transformation. As a result,
studies on the pneumococcal genome provided an initial overview of the genetic potential of
this pathogen. The pneumococcus is a highly versatile bacterium possessing a high rate of
uptake and recombination of exogenous DNA from neighboring bacteria. As such, a significant
diversity in the genome content among the different pneumococcal strains has been reported.
The capsular polysaccharide, an important pneumococcal virulence factor, is the best example
on the pneumococcal diversity. There are over 98 serotypes characterized to date presenting
differences in their capsule (cps) locus. Additional to the cps locus, the pneumococcus also
presents 13 genomic islets annotated as regions of diversity (RD) encoded in the auxiliary
genome. Remarkably, 8 of the pneumococcal RD studied so far have been associated with
virulence. Furthermore, the ongoing sequencing of over 4000 pneumococcal genomes have
shed light on the conservation level of well-known pneumococcal virulence factors.
Interestingly, important pneumococcal virulence determinants show variations in the gene and
protein sequence among the different strains. Prototypes are for example the pneumococcal
surface protein C (PspC) and pneumococcal adherence and virulence factor B (PavB).
Conversely, gene regulation in S. pneumoniae is carried out by highly conserved and genome-
wide distributed transcriptional factors. Overall, the pneumococci interplays with its
environment with 4 major regulatory systems: quorum sensing (QS), stand-alone
transcriptional regulators, small RNAs (sRNAs) and two-component regulatory systems (TCS).
Some of these systems are multifaceted and share more than one feature. Furthermore, there
is crosstalk among the different systems, requiring the activation of a signaling cascade to
function properly.
A comprehensive analysis of the distribution and conservation of pneumococcal
virulence factors and TCS was obtained in this study. The results are summarized as a
simplified variome in which 25 pneumococcal strains with a complete sequenced genome were
analyzed. Interestingly, the genes encoding the glycolytic protein enolase and the toxin
pneumolysin were the most conserved virulence determinants. Additionally, the high level of
conservation was confirmed for the pneumococcal TCS regulators, especially for WalKR,
CiaRH and TCS08.
The main focus of this study was on the regulatory functions of pneumococcal TCS.
With this in mind, an extensive and detailed systematic review of the 13 pneumococcal TCS
and its orphan RR was undertaken. For this purpose, every pneumococcal TCS was analyzed
for its reported functional and structural information along with its contribution to the main
pathophysiology of the pneumococci. In brief, S. pneumoniae can utilize its TCS for the
regulation of important cellular processes and the sensing of detectable signals in the
environment. Additionally, the role of TCS in pneumococcal processes and signal sensing can
be divided further. In the first place, pneumococcal TCS regulate competence and fratricide,
the production of bacteriocins and host-pathogen interaction processes, while the detectable
signals include cell-wall perturbations, environmental stress, and nutrients. As a conclusion
from this section, it is possible to analyze the pneumococcal TCS in a comprehensive manner.
There is a complex network among the different pneumococcal regulators and the TCS play
an important role. Moreover, these systems are highly conserved and essential for the proper
functioning of the pneumococcus as a pathogen.
Following up on pneumococcal TCS, this study focused especially on the TCS08.
Interestingly, the pneumococcal TCS08 has been previously associated with the regulation of the cellobiose metabolism. Furthermore, this system has also been reported to regulate the
expression of genes encoded in the RD4 (Pilus-1). Remarkably, the pneumococcal TCS08
was shown to be highly homologous to the SaeRS system of Staphylococcus aureus. Initially,
mutant strains lacking a single (Δrr08 or Δhk08) or both components (Δtcs08) of the TCS08
were generated in pneumococcal D39 and TIGR4 strains. Transcriptomics and functional
assays showed a downregulation of the PI-1 in the absence of the complete tcs08, while PavB
presented an upregulation in the Δhk08 knockout. Moreover, an important number of genes
coding for intermediary metabolism proteins were also found to be differentially expressed by
microarray analysis. As such, the TIGR4Δhk08 strain presented a downregulation for the
cellobiose operon (cel). In contrast, an upregulation was reported for the fatty acid biosynthesis
(fab) and arginine catabolism (arc) operons. Conversely, a decrease in gene expression was
seen in the TIGR4Δrr08 strain for the arc operon. Finally, in vivo murine pneumonia and sepsis
models highlighted an involvement of TCS08 in pneumococcal virulence. Remarkably, the
different TCS08 mutants presented a strain dependent effect on their virulence severity. The
TIGR4Δrr08, and all TCS08 mutants in D39 showed a decrease in virulence in the pneumonia
model, with no changes in sepsis. Conversely, the absence of HK08 in TIGR4 presented a
highly virulent phenotype in both pneumonia and sepsis models. To sum up, the pneumococcal
TCS08 influenced the expression of genes involved in fitness and colonization. Specifically,
those coding for the adhesins PavB and PI-1 and fitness proteins from the cel, arc and fab
operons. Remarkably, the highest changes in expression were observed in the strains lacking
the HK08. Additionally, TCS08 has a strain dependent impact on pneumococcal virulence as
showed by murine pneumonia and sepsis models when comparing the effects in D39 and
TIGR4.