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Like eukaryotes, different bacterial species express one or more Ser/Thr kinases and phosphatases that operate in various signaling networks by catalyzing phosphorylation and dephosphorylation of proteins that can immediately regulate biochemical pathways by altering protein function. The human pathogen Streptococcus pneumoniae encodes a single Ser/Thr kinase-phosphatase couple known as StkP-PhpP, which has shown to be crucial in the regulation of cell wall synthesis and cell division. In this study, we applied proteomics to further understand the physiological role of pneumococcal PhpP and StkP with an emphasis on phosphorylation events on Ser and Thr residues. Therefore, the proteome of the non-encapsulated D39 strain (WT), a kinase (ΔstkP), and phosphatase mutant (ΔphpP) were compared in a mass spectrometry based label-free quantification experiment. Results show that a loss of function of PhpP causes an increased abundance of proteins in the phosphate uptake system Pst. Quantitative proteomic data demonstrated an effect of StkP and PhpP on the two-component systems ComDE, LiaRS, CiaRH, and VicRK. To obtain further information on the function, targets and target sites of PhpP and StkP we combined the advantages of phosphopeptide enrichment using titanium dioxide and spectral library based data evaluation for sensitive detection of changes in the phosphoproteome of the wild type and the mutant strains. According to the role of StkP in cell division we identified several proteins involved in cell wall synthesis and cell division that are apparently phosphorylated by StkP. Unlike StkP, the physiological function of the co-expressed PhpP is poorly understood. For the first time we were able to provide a list of previously unknown putative targets of PhpP. Under these new putative targets of PhpP are, among others, five proteins with direct involvement in cell division (DivIVA, GpsB) and peptidoglycan biosynthesis (MltG, MreC, MacP).
Streptococcus pneumoniae is a commensal of the human upper respiratory tract and moreover, the
causative agent of several life-threatening diseases including pneumonia, sepsis, otitis media, and
meningitis. Due to the worldwide rise of resistance to antibiotics in pneumococci the understanding
of its physiology is of increasing importance. In this context, the analysis of the pneumococcal
proteome is helpful as comprehensive data on protein abundances in S. pneumoniae may provide
an extensive source of information to facilitate the development of new vaccines and drug
treatments.
It is known that protein phosphorylation on serine, threonine and tyrosine residues is a major
regulatory post-translational modification in pathogenic bacteria. This reversible post-translational
modification enables the translation of extracellular signals into cellular responses and therewith
adaptation to a steadily changing environment. Consequently, it is of particular interest to gather
precise information about the phosphoproteome of pneumococci. S. pneumoniae encodes a single
Serine/Threonine kinase-phosphatase couple known as StkP-PhpP.
To address the global impact and physiological importance of StkP and PhpP which are closely
linked to the regulation of cell morphology, growth and cell division in S. pneumoniae, proteomics
with an emphasis on phosphorylation and dephosphorylation events on Ser and Thr residues was
applied. Thus, the non-encapsulated pneumococcal D39Δcps strain (WT), a kinase (ΔstkP) and
phosphatase mutant (ΔphpP) were analyzed in in a mass spectrometry based label-free
quantification experiment. The global proteome analysis of the mutants deficient for stkP or phpP
already proved the essential role of StkP-PhpP in the protein regulation of the pneumococcus.
Proteins with significantly altered abundances were detected in diverse functional groups in both
mutants. Noticeable changes in the proteome of the stkP deletion mutant were observed in
metabolic processes such as “Amino acid metabolism” and also in pathways regulating genetic
and environmental information processing like “Transcription” and “Signal transduction”.
Prominent changes in the metabolism of DNA, nucleotides, carbohydrates, cofactors and vitamins
as well as in the categories “Transport and binding proteins” and “Glycan biosynthesis and
metabolism” have been additionally detected in the proteome of the phosphatase mutant. Still, the
quantitative comparison of WT and mutants revealed more significantly altered proteins in ΔphpP
than in ΔstkP. Moreover, the results indicated that the loss of function of PhpP causes an increased
abundance of proteins in the pneumococcal phosphate uptake system Pst. Furthermore, the
obtained quantitative proteomic data revealed an influence of StkP and PhpP on the twocomponent
systems ComDE, LiaRS, CiaRH, and VicRK.
Recent studies of the pneumococcal StkP/PhpP couple demonstrated that both proteins play an
essential role in cell growth, cell division and separation. Growth analyses and the phenotypic
characterization of the mutants by electron-microscopy performed within this work pointed out
that ΔphpP and ΔstkP had different growth characteristics and abnormal cell division and cell
separation. Nevertheless, the morphological effects could not be explained by changes in protein
abundances on a global scale. So, the in-depth analysis of the phosphoproteome was mandatory
to deliver further information of PhpP and StkP and their influence in cell division and
peptidoglycan synthesis by modulating proteins involved in this mechanisms.
For more detailed insights into the activity, targets and target sites of PhpP and StkP the advantages
of phosphopeptide enrichment using titanium dioxide and spectral library based data evaluation
were combined. Indeed, the application of an adapted workflow for phosphoproteome analyses
and the use of a recently constructed broad spectral library, including a large number of
phosphopeptides (504) highly enhanced the reliable and reproducible identification of
phosphorylated proteins in this work.
Finally, already known targets and target sites of StkP and PhpP, detected and described in other
studies using different experimental procedures, have been identified as a proof of principle
applying the mass spectrometry based phosphoproteome approach presented in this work.
Referring to the role of StkP in cell division and cell separation a number of proteins participating
in cell wall synthesis and cell division that are apparently phosphorylated by StkP was identified.
In comparison to StkP, the physiological function and role of the co-expressed phosphatase PhpP
is poorly understood. But, especially the list of previously unknown putative target substrates of
PhpP has been extended remarkably in this work. Among others, five proteins with direct
involvement in cell division (DivIVA, GpsB) and peptidoglycan biosynthesis (MltG, MreC, MacP)
can be found under the new putative targets of PhpP.
All in all, this work provides a complex and comprehensive protein repository of high proteome
coverage of S. pneumoniae D39 including identification of yet unknown serine/threonine/tyrosine
phosphorylation, which might contribute to support various research interests within the scientific
community and will facilitate further investigations of this important human pathogen.
Clostridioides difficile is an intestinal human pathogen that uses the opportunity of a depleted microbiota to cause an infection. It is known, that the composition of the intestinal bile acid cocktail has a great impact on the susceptibility toward a C. difficile infection. However, the specific response of growing C. difficile cells to diverse bile acids on the molecular level has not been described yet. In this study, we recorded proteome signatures of shock and long-term (LT) stress with the four main bile acids cholic acid
(CA), chenodeoxycholic acid (CDCA), deoxycholic acid (DCA), and lithocholic acid (LCA). A general overlapping response to all tested bile acids could be determined particularly in shock experiments which appears plausible in the light of their common steroid structure. However, during LT stress several proteins showed an altered abundance
in the presence of only a single or a few of the bile acids indicating the existence of specific adaptation mechanisms. Our results point at a differential induction of the groEL and dnaKJgrpE chaperone systems, both belonging to the class I heat shock genes. Additionally, central metabolic pathways involving butyrate fermentation and the reductive Stickland fermentation of leucine were effected, although CA caused a
proteome signature different from the other three bile acids. Furthermore, quantitative proteomics revealed a loss of flagellar proteins in LT stress with LCA. The absence of flagella could be substantiated by electron microscopy which also indicated less
flagellated cells in the presence of DCA and CDCA and no influence on flagella formation by CA. Our data break down the bile acid stress response of C. difficile into a general and a specific adaptation. The latter cannot simply be divided into a response to primary and secondary bile acids, but rather reflects a complex and variable adaptation process enabling C. difficile to survive and to cause an infection in the intestinal tract.