Stephan Michalik

Global impact of protein arginine phosphorylation on the physiology of Bacillus subtilis

Reversible protein phosphorylation is an important and ubiquitous protein modification in all living cells. Here we report that protein phosphorylation on arginine residues plays a physiologically significant role. We detected 121 arginine phosphorylation sites in 87 proteins in the Gram-positive model organism Bacillus subtilis in vivo. Moreover, we provide evidence that protein arginine phosphorylation has a functional role and is involved in the regulation of many critical cellular processes, such as protein degradation, motility, competence, and stringent and stress responses. Our results suggest that in B. subtilis the combined activity of a protein arginine kinase and phosphatase allows a rapid and reversible regulation of protein activity and that protein arginine phosphorylation can play a physiologically important and regulatory role in bacteria.

Trapping and Proteomic Identification of Cellular Substrates of the ClpP Protease in Staphylococcus aureus

In the important human pathogen Staphylococcus aureus the cytoplasmic ClpP protease is essential for mounting cellular stress responses and for virulence. To directly identify substrates of the ClpP protease, we expressed in vivo a proteolytic inactive form of ClpP (ClpP(trap)) that will retain but not degrade substrates translocated into its proteolytic chamber. Substrates captured inside the proteolytic barrel were co-purified along with the His-tagged ClpP complex and identified by mass spectrometry. In total, approximately 70 proteins were trapped in both of the two S. aureus strains NCTC8325-4 and Newman. About one-third of the trapped proteins are previously shown to be unstable or to be substrates of ClpP in other bacteria, supporting the validity of the ClpP-TRAP. This group of proteins encompassed the transcriptional regulators CtsR and Spx, the ClpC adaptor proteins McsB and MecA, and the cell division protein FtsZ. Newly identified ClpP substrates include the global transcriptional regulators PerR and HrcA, proteins involved in DNA damage repair (RecA, UvrA, UvrB), and proteins essential for protein synthesis (RpoB and Tuf). Our study hence underscores the central role of Clp-proteolysis in a number of pathways that contribute to the success of S. aureus as a human pathogen.

CtsR, the Gram-positive master regulator of protein quality control, feels the heat

Protein quality networks are required for the maintenance of proper protein homeostasis and essential for viability and growth of all living organisms. Hence, regulation and coordination of these networks are critical for survival during stress as well as for virulence of pathogenic species. In low GC, Gram‐positive bacteria central protein quality networks are under the control of the global repressor CtsR. Here, we provide evidence that CtsR activity during heat stress is mediated by intrinsic heat sensing through a glycine‐rich loop, probably in all Gram‐positive species. Moreover, a function for the recently identified arginine kinase McsB is confirmed, however, not for initial inactivation and dissociation of CtsR from the DNA, but for heat‐dependent auto‐activation of McsB as an adaptor for ClpCP‐mediated degradation of CtsR.

Staphylococcus aureus Transcriptome Architecture: From Laboratory to Infection-Mimicking Conditions

Staphylococcus aureus is a major pathogen that colonizes about 20% of the human population. Intriguingly, this Gram-positive bacterium can survive and thrive under a wide range of different conditions, both inside and outside the human body. Here, we investigated the transcriptional adaptation of S. aureus HG001, a derivative of strain NCTC 8325, across experimental conditions ranging from optimal growth in vitro to intracellular growth in host cells. These data establish an extensive repertoire of transcription units and non-coding RNAs, a classification of 1412 promoters according to their dependence on the RNA polymerase sigma factors SigA or SigB, and allow identification of new potential targets for several known transcription factors. In particular, this study revealed a relatively low abundance of antisense RNAs in S. aureus, where they overlap only 6% of the coding genes, and only 19 antisense RNAs not co-transcribed with other genes were found. Promoter analysis and comparison with Bacillus subtilis links the small number of antisense RNAs to a less profound impact of alternative sigma factors in S. aureus. Furthermore, we revealed that Rho-dependent transcription termination suppresses pervasive antisense transcription, presumably originating from abundant spurious transcription initiation in this A+T-rich genome, which would otherwise affect expression of the overlapped genes. In summary, our study provides genome-wide information on transcriptional regulation and non-coding RNAs in S. aureus as well as new insights into the biological function of Rho and the implications of spurious transcription in bacteria.

Staphylococcal serine protease–like proteins are pacemakers of allergic airway reactions to Staphylococcus aureus

Background: A substantial subgroup of asthmatic patients have “nonallergic” or idiopathic asthma, which often takes a severe course and is difficult to treat. The cause might be allergic reactions to the gram‐positive pathogen Staphylococcus aureus, a frequent colonizer of the upper airways. However, the driving allergens of S aureus have remained elusive. Objective: We sought to search for potentially allergenic S aureus proteins and characterize the immune response directed against them. Methods: S aureus extracellular proteins targeted by human serum IgG4 were identified by means of immunoblotting to screen for potential bacterial allergens. Candidate antigens were expressed as recombinant proteins and used to analyze the established cellular and humoral immune responses in healthy adults and asthmatic patients. The ability to induce a type 2 immune response in vivo was tested in a mouse asthma model. Results: We identified staphylococcal serine protease–like proteins (Spls) as dominant IgG4‐binding S aureus proteins. SplA through SplF are extracellular proteases of unknown function expressed by S aureus in vivo. Spls elicited IgE antibody responses in most asthmatic patients. In healthy S aureus carriers and noncarriers, peripheral blood T cells elaborated TH2 cytokines after stimulation with Spls, as is typical for allergens. In contrast, TH1/TH17 cytokines, which dominated the response to S aureus &agr;‐hemolysin, were of low concentration or absent. In mice inhalation of SplD without adjuvant induced lung inflammation characterized by TH2 cytokines and eosinophil infiltration. Conclusion: We identify Spls as triggering allergens released by S aureus, opening prospects for diagnosis and causal therapy of asthma.

Life and Death of Proteins: A Case Study of Glucose-starved Staphylococcus aureus

The cellular amount of proteins not only depends on synthesis but also on degradation. Here, we expand the understanding of differential protein levels by complementing synthesis data with a proteome-wide, mass spectrometry-based stable isotope labeling with amino acids in cell culture analysis of protein degradation in the human pathogen Staphylococcus aureus during glucose starvation. Monitoring protein stability profiles in a wild type and an isogenic clpP protease mutant revealed that 1) proteolysis mainly affected proteins with vegetative functions, anabolic and selected catabolic enzymes, whereas the expression of TCA cycle and gluconeogenesis enzymes increased; 2) most proteins were prone to aggregation in the clpP mutant; 3) the absence of ClpP correlated with protein denaturation and oxidative stress responses, deregulation of virulence factors and a CodY repression. We suggest that degradation of redundant, inactive proteins disintegrated from functional complexes and thereby amenable to proteolytic attack is a fundamental cellular process in all organisms to regain nutrients and guarantee protein homeostasis.

Proteolysis during long-term glucose starvation in Staphylococcus aureus COL

A combination of pulse‐chase experiments and 2‐D PAGE revealed that protein degradation appears to play a crucial role for the cell physiology of Staphylococcus aureus COL during extended periods of glucose starvation. The synthesis rate of virtually all cytosolic and radioactively labeled proteins from growing cells seemed dramatically reduced in the first 3.5 h of glucose starvation. The stability of proteins synthesized in growing cells was monitored by a pulse‐chase approach on a proteome wide scale. Especially, enzymes involved in nucleic acid and amino acid biosyntheses, energy metabolism and biosynthesis of cofactors were found rather rapidly degraded within the onset of the stationary phase, whereas the majority of glycolytic and tricarboxylic acid cycle enzymes remained more stable. Furthermore, single enzymes of biosynthetic pathways were differentially degraded. A metabolite analysis revealed that glucose completely depleted from the medium in the transient phase, and amino acids such as alanine and glycine were taken up by the cells in the stationary phase. We suggest that vegetative proteins no longer required in non‐growing cells and thus no longer protected by integration into functional complexes were degraded. Proteolysis of putative non‐substrate‐bound or “unemployed” proteins appears to be a characteristic feature of S. aureus in order to access nutrients as an important survival strategy under starvation conditions.

Comparative proteome analysis reveals conserved and specific adaptation patterns of Staphylococcus aureus after internalization by different types of human non-professional phagocytic host cells.

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 pathogens 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.

Specific serum IgG at diagnosis of Staphylococcus aureus bloodstream invasion is correlated with disease progression

UNLABELLED Although Staphylococcus aureus is a prominent cause of infections, no vaccine is currently available. Active vaccination relies on immune memory, a core competence of the adaptive immune system. To elucidate whether adaptive immunity can provide protection from serious complications of S. aureus infection, a prospective observational study of 44 patients with S. aureus infection complicated by bacteremia was conducted. At diagnosis, serum IgG binding to S. aureus extracellular proteins was quantified on immunoblots and with Luminex-based FLEXMAP 3D™ assays comprising 64 recombinant S. aureus proteins. Results were correlated with the course of the infection with sepsis as the main outcome variable. S. aureus-specific serum IgG levels at diagnosis of S. aureus infection were lower in patients developing sepsis than in patients without sepsis (P<0.05). The pattern of IgG binding to eight selected S. aureus proteins correctly predicted the disease course in 75% of patients. Robust immune memory of S. aureus was associated with protection from serious complications of bacterial invasion. Serum IgG binding to eight conserved S. aureus proteins enabled stratification of patients with high and low risk of sepsis early in the course of S. aureus infections complicated by bacteremia. SIGNIFICANCE S. aureus is a dangerous pathogen of ever increasing importance both in hospitals and in the community. Due to the crisis of antibiotic resistance, an urgent need exists for new strategies to combat S. aureus infections, such as vaccination. To date, however, all vaccine trials have failed in clinical studies. It is therefore unclear whether the adaptive immune system is at all able to control S. aureus in humans. The paper demonstrates the use of proteomics for providing an answer to this crucial question. It describes novel results of a prospective study in patients with S. aureus infection complicated by bloodstream invasion. Immune proteomic analysis shows that robust immune memory of S. aureus - reflected by strong serum IgG antibody binding to S. aureus antigens - is associated with clinical protection from sepsis. This lends support to the notion of a vaccine to protect against the most serious complications of S. aureus infection. Hence, the data encourage further efforts in vaccine development.

Activation of the alternative sigma factor SigB of Staphylococcus aureus following internalization by epithelial cells - an in vivo proteomics perspective.

Staphylococcus aureus is a versatile pathogen that can be a commensal but also cause a wide range of different infections. This broad disease spectrum is a reflection of the complex regulation of a large collection of virulence factors that together with metabolic fitness allow adaptation to different niches. The alternative sigma factor SigB is one of the global regulators mediating this adaptation. However, even if SigB contributes to expression of many virulence factors its importance for successful infection greatly varies with the strain and the infection setting analyzed. We have recently established a proteomics workflow that combines high efficiency cell sorting with sensitive mass spectrometry and allows monitoring of global proteome adaptations with roughly one million bacterial cells. Thus, we can now approach the adaptation of pathogens to the intracellular milieu. In the current study this proteomics workflow was used in conjunction with qRT-PCR and confocal fluorescence microscopy to comparatively analyze the adaptation of the S. aureus wild type strain HG001 and its isogenic sigB mutant to the intracellular milieu of human S9 bronchial epithelial cells. The study revealed fast and transient activation of SigB following internalization by human host cells and the requirement of SigB for intracellular growth. Loss of SigB triggered proteome changes reflecting the different residual growth rates of wild type and sigB mutant, respectively, the resistance to methicillin, adaptation to oxidative stress and protein quality control mechanisms.