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Urm1: A Non-Canonical UBL
(2021)
Streptococcus pneumoniae (the pneumococcus) is a harmless resident of the human nasopharyngeal cavity, and, in general, every individual is likely to be colonized asymptomatically at least once during life. However, under certain conditions, the bacterium can spread to other tissues and organs causing local, non-invasive infections but also lifethreatening, invasive diseases. Pneumococcal carriage and infection is a highly regulated interplay between pathogen- and host-specific factors and the intimate contact of S. pneumoniae with the surface of the nasopharynx is the crucial step in pneumococcal pathogenesis. Pneumococcal adherence to the respiratory epithelium is mediated by surface-exposed adhesins. These adhesins engage host cell receptors either directly or indirectly by recognizing glycoproteins of the extracellular matrix (ECM) including structural components, such as collagens, laminins, and fibronectins, as well as plasma-derived ECM modulators, like vitronectin and Factor H. Pneumococcal surface protein C (PspC) is a surface-exposed protein and important virulence factor of S. pneumoniae. The multifunctional PspC protein promotes pneumococcal adherence to host cells by interacting with the secretory component of the human polymeric Immunoglobulin receptor of respiratory cells. In addition, PspC facilitates pneumococcal immune evasion by recruiting the complement inhibitor proteins C4b-binding protein (C4BP) and Factor H. Moreover, Factor H bound to the pneumococcal surface promotes bacterial adhesion to human epithelial and endothelial cells. S. pneumoniae also interacts with the human glycoprotein vitronectin. In plasma, monomeric vitronectin regulates thrombosis, fibrinolysis and the terminal complement cascade, while it additionally mediates cell-matrix interactions, cell adhesion and migration in the ECM. It was shown that multimeric, ECM-associated vitronectin facilitates pneumococcal adherence to respiratory epithelial cells. In addition, the interaction of pneumococci with vitronectin promotes their uptake by mucosal epithelial cells via the engagement of the integrin αvβ3 receptor and activation of intracellular signaling pathways culminating in cytoskeletal rearrangements. This study aims to identify and characterize the surface-exposed protein(s) that mediate binding of pneumococci to vitronectin and to elucidate the impact of vitronectin on pneumococcal pathogenesis beyond its function as molecular bridge between pneumococcus and host. Flow cytometric, immunosorbent and surface plasmon resonance experiments revealed that PspC is a vitronectin-binding protein of S. pneumoniae. The specificity of the interaction with vitronectin was confirmed using recombinant PspC proteins and Lactococcus lactis heterologously expressing PspC on their surface. Factor H did not hinder vitronectinbinding to PspC indicating that vitronectin recognizes the central part of PspC. Secretory IgA inhibited but not completely prevented vitronectin-binding to PspC, strongly suggesting that vitronectin binds near, but not directly to, the SC-binding region within the R domain(s) of PspC. In addition, PspC proteins comprising two R domains bound with higher affinity to vitronectin than PspC containing only one R domain, indicating that two interconnected R domains are required for efficient vitronectin-binding. Despite the sequential and structural differences to classical PspC, the PspC-like protein Hic specifically interacted with vitronectin with similar affinity than PspC containing two linked R domains. Binding studies confirmed that Factor H interacts with the very N-terminal region of Hic showing high sequence homology to classical PspC proteins, while vitronectin recognizes an adjacent region in the N-terminal region of Hic. The studied PspC proteins bound to both soluble and immobilized vitronectin, and the C-terminal heparin-binding domain (HBD3) was identified as PspC-binding motif in soluble vitronectin. However, in its immobilized form, vitronectin likely exposes additional binding sites for PspC since a region N-terminally to the identified HBD3 conferred binding of PspC. Vitronectin inhibits the terminal complement pathway, thereby preventing proinflammatory immune reactions and tissue damage. In general, pneumococci are protected from opsonization and MAC-dependent lysis by their capsule. However, pneumococci in close contact to human cells can become susceptible to complement attack due to reduced amounts of capsule. In addition, they can be severely affected by TCC-induced inflammatory responses. Vitronectin bound to PspC significantly inhibited the formation of terminal complement complexes. Thus, the interaction of PspC with vitronectin might aid in immune evasion of S. pneumoniae by inhibiting complement-mediated lysis and/or suppressing proinflammatory events. In conclusion, the results revealed the multifunctional PspC and Hic as vitronectin-binding proteins and proposed a novel role for the specific interaction of S. pneumoniae with vitronectin in regulating the complement cascade, beside its function as molecular bridge to the respiratory epithelium.
Bacteria are exposed to oxidative stress as an unavoidable consequence of their aerobic lifestyle. Reactive oxygen species (ROS) are generated in the stepwise one-electron reduction of molecular oxygen during the respiration. Pathogens encounter ROS during the oxidative burst of macrophages as part of the host immune defense. Besides ROS, bacteria also have to cope with reactive chlorine, electrophilic and nitrogen species (RCS, RES, RNS). To cope with these reactive species, bacteria have evolved different defense and repair mechanisms. To maintain the reduced state of the cytoplasm, they utilize low molecular weight (LMW) thiols. LMW thiols are small thiol-containing compounds that can undergo post-translational thiolmodifications with protein thiols, termed as S-thiolations. S-thiolations function as major redox regulatory and thiol-protection mechanism under oxidative stress conditions. In eukaryotes and Gram-negative bacteria, the tripeptide glutathione (GSH) functions as major LMW thiol, which is present in millimolar concentrations. The Actinomycetes, such as Mycobacterium and Corynebacterium species do not produce GSH and utilize instead mycothiol (MSH) as their alternative LMW thiol. In Firmicutes, including Bacillus and Staphylococcus species, bacillithiol (BSH) functions as the major LMW thiol. LMW thiols protect protein thiols against the irreversible overoxidation of cystein residues to sulfinic and sulfonic acids. In addition, LMW thiols contribute to the virulence and survival of pathogens, function in metal homeostasis and serve as enzyme cofactors for detoxification of xenobiotics and antibiotics. In this doctoral thesis, we aimed to investigate the roles of MSH and BSH in redox regulation of main metabolic enzymes under oxidative stress in the pathogens Corynebacterium diphtheriae and Staphylococcus aureus. Previous redox proteomics studies identified the glyceraldehyde-3-phosphate dehydrogenase GapDH and the aldehyde dehydrogenase AldA as S-thiolated in S. aureus and C. diphtheriae. Thus, we aimed to study the redox regulation of the metabolic enzyme GapDH in C. diphtheriae in response to NaOCl and H2O2 stress by S-mycothiolation, which is described in chapter 1. Moreover, we studied the involvement of the mycoredoxin-1 (Mrx1) and thioredoxin (Trx) pathways in reactivation of S-mycothiolated GapDH in vitro. Using shotgun proteomics, 26 S-mycothiolated proteins were identified under NaOCl stress in C. diphtheriae. These are involved in energy metabolism (Ndh, GlpD) and in the biosynthesis of amino acids (ThrA, LeuB), purines (PurA) and cell wall metabolites (GlmS). The glycolytic GapDH was identified as conserved target for S-thiolation across Gram-positive bacteria. GapDH was the most abundant protein, contributing with 0.75 % to the total cystein proteome. Moreover, GapDH is a conserved target for redox regulation and S-glutathionylation in response to oxidative stress in several prokaryotic and eukaryotic organisms. Treatment of GapDH with NaOCl and H2O2 in the absence of MSH resulted in irreversible enzyme inactivation due to overoxidation. Pretreatment of GapDH with MSH prior to H2O2 or NaOCl exposure resulted in reversible inactivation due to S-mycothiolation of the active site Cys153. Since S-mycothiolation is faster compared to overoxidation, S-mycothiolation efficiently protects the GapDH active site against overoxidation. The activity of S-mycothiolated GapDH could be restored by both, the Mrx1 and Trx pathway in vitro. Interestingly, the recovery of Smycothiolated GapDH by Mrx1 was faster compared to its reduction by the Trx pathway. In previous studies, the reactivation of S-mycothiolated Mpx and MrsA by the mycoredoxin pathway occurred also faster compared to the Trx pathway, which is consistent with our results. We were further interested to analyze the redox regulation of the glyceraldehyde-3phosphate dehydrogenase Gap of S. aureus under NaOCl and H2O2 stress, which is described in chapter 2. Using the quantitative redox proteomic approach OxICAT, 58 NaOCl-sensitive cystein residues with >10% thiol oxidation under NaOCl stress were identified. Gap and AldA showed the highest oxidation increase of 29% under NaOCl stress at their active site cystein residues. Using shotgun proteomics, five S-bacillithiolated proteins were identified, including Gap, AldA, GuaB, RpmJ and PpaC. Gap contributed with 4 % as most abundant cystein protein to the total cystein proteome. Our activity assays demonstrated that Gap of S. aureus is highly sensitive to overoxidation by H2O2 and NaOCl in vitro in the absence of BSH. The active site Cys151 of Gap was oxidized to the BSH mixed disulfide under H2O2 and NaOCl stress in the presence of BSH in vitro, which resulted in the reversible Gap inactivation. Moreover, inactivation of Gap by NaOCl and H2O2 due to S-bacillithiolation was faster compared to overoxidation, indicating that S-bacillithiolation protects the Gap active site against overoxidation in vitro. We further showed that the bacilliredoxin Brx catalyzes the reduction of S-bacillithiolated Gap in vitro. Molecular docking of BSH into the Gap active site revealed that S-bacillithiolation does not require major structural changes. Apart from Gap, the aldehyde dehydrogenase AldA was identified as S-bacillithiolated at its active site Cys279 under NaOCl stress in S. aureus previously. Thus, the expression, function, redox regulation and structural changes of AldA were analysed under NaOCl and aldehyde stress in S. aureus as summarized in chapter 3. AldA was S-bacillithiolated in the presence of H2O2 and BSH as demonstrated in BSH-specific Western blots in vitro. The expression of aldA was previously shown to be regulated by the alternative sigma factor SigmaB in S. aureus. Transcription of aldA was strongly increased in a SigmaB-independent manner under formaldehyde, NaOCl and diamide stress in S. aureus. Using an aldA deletion mutant, we demonstrated that aldA is required for growth and survival under NaOCl stress in S. aureus. The purified AldA enzyme was shown to catalyze the oxidation of various aldehyde substrates, including formaldehyde, methylglyoxal, glycolaldehyde and acetaldehyde in vitro. In addition, the function of the conserved Cys279 for AldA activity was investigated in vivo and in vitro. The purified AldAC279S mutant was shown to be inactive for aldehyde oxidation in vitro. Moreover, the aldAC279S mutant was very sensitive under NaOCl stress in vivo, and this phenotype could be reversed using the aldA complemented strain. These experiments demonstrate the function of Cys279 for AldA activity both in vitro and in vivo. AldA activity assays showed that AldA is sensitive to overoxidation and irreversible inactivation by H2O2 alone in vitro. In the presence of BSH, AldA is protected against overoxidation by reversible Sbacillithiolation in vitro. Molecular docking and molecular dynamics simulations revealed that BSH occupies two different positions in the Cys279 active site, which depend on the NAD+ cofactor. In the apoenzyme, BSH forms the disulfide with Cys279 in the “resting” state position, while Cys279 is S-bacillithiolated in the “attacking” state position in the holoenzyme in the presence of the NAD+ cofactor.
The leading hypothesis of why organisms age is the “Free Radical Theory of Aging”, which states that the accumulation of reactive oxygen species (ROS), such as superoxide (O2•-) and hydrogen peroxide (H2O2), causes protein, lipid and DNA damage and leads to the observed age-related decline of cells and tissues. A major obstacle in analyzing the role of oxidative stress in aging organisms is the inability to precisely localize and quantify the oxidants, to identify proteins and pathways that might be affected, and ultimately, to correlate changes in oxidant levels with the lifespan of the organism. To directly monitor the onset and extent of oxidative stress during the lifespan of Caenorhabditis elegans, we utilized the fluorescent H2O2 sensor protein HyPer, which enabled us to quantify endogenous peroxide levels in different tissues of living animals in real time. We made the surprising observation that wildtype C. elegans is exposed to very high peroxide levels during development. Peroxide levels drop rapidly as the animals mature, and low peroxide levels then prevail throughout the reproductive age, after which an age-accompanying increase of peroxide level is observed. These results were in excellent agreement with findings obtained by using the highly quantitative redox proteomic technique OxICAT, which monitors the oxidation status of redox-sensitive proteins as read-out for onset, localization, and protein targets of oxidative stress. By using OxICAT, we detected increased protein thiol oxidation during the development of C. elegans and in aging animals. Many processes in C. elegans might potentially contribute to the elevated peroxide levels observed during development, including cuticle formation, apoptosis, proliferation, gametogenesis, or ROS signaling. The finding that all investigated C. elegans mutants regardless of their lifespan are exposed to high developmental peroxide levels argues for ROS accumulation to be a universal and necessary event. Yet, recovery from the early oxidative boost might determine the subsequent adult lifespan, as we found that long-lived daf-2 mutants transition faster to reducing conditions than short-lived daf-16 mutants, which retain higher peroxide levels throughout their mature life. These results suggest that changes in the cellular oxidant homeostasis, encountered at a very early stage in life, might determine subsequent redox levels and potentially the lifespan of organisms. Manipulation of developmental oxidant levels using glucose restriction or a short bolus of superoxide caused a disruption in developmental growth, a delay in reproduction, and a shortened lifespan. These results suggest that developmental oxidant levels are fine-tuned and optimized. Future experiments are aimed to investigate the sources of developmental hydrogen peroxide, and to elucidate whether active down-regulation of antioxidant enzymes during the larval period might foster peroxide accumulation. Preliminary results indicate that this might indeed be the case for peroxiredoxin 2, whose expression was significantly lower during development than at later stages in life. Finally, we investigated whether the observed variances in the developmental peroxide levels of individual worms within a synchronized wildtype population might be responsible for the observed significant variances in lifespan, and hence could serve as a predictor for adult lifespan. Preliminary results revealed that neither too low nor too high peroxide levels during development are beneficial for the lifespan of wildtype worms, suggesting that ROS level during development might be optimized for maximized lifespan. Future experiments aim to reveal the processes that are affected by ROS and which might influence the individual’s lifespan early in life.
Proteasomes comprise a family of proteasomal complexes essential for maintaining protein homeostasis. Accordingly, proteasomes represent promising therapeutic targets in multiple human diseases. Several proteasome inhibitors are approved for treating hematological cancers. However, their side effects impede their efficacy and broader therapeutic applications. Therefore, understanding the biology of the different proteasome complexes present in the cell is crucial for developing tailor-made inhibitors against specific proteasome complexes. Here, we will discuss the structure, biology, and function of the alternative Proteasome Activator 200 (PA200), also known as PSME4, and summarize the current evidence for its dysregulation in different human diseases. We hereby aim to stimulate research on this enigmatic proteasome regulator that has the potential to serve as a therapeutic target in cancer.
Invasion of the bacterial pathogen Listeria monocytogenes into human host cells requires specialized surface molecules for attachment and induction of phagocytosis. However, efficient invasion is also dependent on factors with house-keeping functions, such as SecA2-dependent secretion of autolysins for post-divisional segregation of daughter cells. Mutations in this pathway prevent degradation of peptidoglycan cross-walls, so that long cell chains are formed that cannot be phagocytosed. The extreme chaining of such mutants manifests as rough colony phenotype. One rough clone was isolated from a transposon library with a transposon insertion in the uncharacterized lmo0720 gene (lftS) together with a spontaneous point mutation in the secA2 gene. We separated both mutations and demonstrated that this point mutation in the intramolecular regulator 2 domain of SecA2 was sufficient to inactivate the protein. In contrast, lftS deletion did not cause a ΔsecA2-like phenotype. lftS is located in an operon with lftR (lmo0719), encoding a PadR-like transcriptional regulator, and lftR deletion affected growth, invasion and day-light dependent coordination of swarming. Inactivation of lftS partially suppressed these phenotypes, suggesting a functional relationship between LftR and LftS. However, the invasion defect of the ΔlftR mutant was only marginally suppressed by lftS removal. LftR regulates expression of the lmo0979–0980 (lieAB) operon, encoding a putative multidrug resistance transporter and lieAB transcription was strongly upregulated in the absence of LftR. Deletion of lieAB in the ΔlftR background restores wild type-like invasion levels. Hence, we conclude that tight transcriptional repression of the lieAB operon is essential for efficient listerial host cell invasion.
Lichens represent self-supporting symbioses, which occur in a wide range of terrestrial habitats and which contribute significantly to mineral cycling and energy flow at a global scale. Lichens usually grow much slower than higher plants. Nevertheless, lichens can contribute substantially to biomass production. This review focuses on the lichen symbiosis in general and especially on the model species Lobaria pulmonaria L. Hoffm., which is a large foliose lichen that occurs worldwide on tree trunks in undisturbed forests with long ecological continuity. In comparison to many other lichens, L. pulmonaria is less tolerant to desiccation and highly sensitive to air pollution. The name-giving mycobiont (belonging to the Ascomycota), provides a protective layer covering a layer of the green-algal photobiont (Dictyochloropsis reticulata) and interspersed cyanobacterial cell clusters (Nostoc spec.). Recently performed metaproteome analyses confirm the partition of functions in lichen partnerships. The ample functional diversity of the mycobiont contrasts the predominant function of the photobiont in production (and secretion) of energy-rich carbohydrates, and the cyanobiont’s contribution by nitrogen fixation. In addition, high throughput and state-of-the-art metagenomics and community fingerprinting, metatranscriptomics, and MS-based metaproteomics identify the bacterial community present on L. pulmonaria as a surprisingly abundant and structurally integrated element of the lichen symbiosis. Comparative metaproteome analyses of lichens from different sampling sites suggest the presence of a relatively stable core microbiome and a sampling site-specific portion of the microbiome. Moreover, these studies indicate how the microbiota may contribute to the symbiotic system, to improve its health, growth and fitness.
Regulated ATP-dependent proteolysis is a common feature of developmental processes and plays also a crucial role during environmental perturbations such as stress and starvation. The Bacillus subtilis MgsR regulator controls a subregulon within the stress- and stationary phase σB regulon. After ethanol exposition and a short time-window of activity, MgsR is ClpXP-dependently degraded with a half-life of approximately 6 min. Surprisingly, a protein interaction analysis with MgsR revealed an association with the McsB arginine kinase and an in vivo degradation assay confirmed a strong impact of McsB on MgsR degradation. In vitro phosphorylation experiments with arginine (R) by lysine (K) substitutions in McsB and its activator McsA unraveled all R residues, which are essentially needed for the arginine kinase reaction. Subsequently, site directed mutagenesis of the MgsR substrate was used to substitute all arginine residues with glutamate (R-E) to mimic arginine phosphorylation and to test their influence on MgsR degradation in vivo. It turned out, that especially the R33E and R94/95E residues (RRPI motif), the latter are adjacently located to the two redox-sensitive cysteines in a 3D model, have the potential to accelerate MgsR degradation. These results imply that selective arginine phosphorylation may have favorable effects for Clp dependent degradation of short-living regulatory proteins. We speculate that in addition to its kinase activity and adaptor function for the ClpC ATPase, McsB might also serve as a proteolytic adaptor for the ClpX ATPase in the degradation mechanism of MgsR.
The influence of regulatory proteins on the physiology and virulence of Streptococcus pneumoniae
(2015)
In conclusion, this work identifies the regulator ArgR2 as activator of the S. pneumoniae TIGR4 arginine deiminase system and arginine-ornithine transporter ArcD, which is needed for uptake of the essential amino acid arginine. Although ArgR2 activates ArcD expression and uptake of arginine is required to maintain pneumococcal fitness, the deficiency of ArgR2 increases TIGR4 virulence under in vivo conditions, suggesting that other factors regulated by ArgR2 counterbalance the reduced uptake of arginine by ArcD. Thus this works illustrates that the physiological homeostasis of pneumococci is complex and that ArgR2 plays a key role in maintaining bacterial fitness. Moreover, Rex was identified as a regulator of housekeeping genes including genes encoding glycolytic enzymes. In vitro studies and gene expression analyses suggested that the regulator Rex does not have an influence on the physiology of S. pneumoniae. However, a co-infection experiment demonstrated that Rex is involved in maintaining pneumococcal fitness and robustness under in vivo conditions.
Allicin (diallyl thiosulfinate) is the major thiol-reactive organosulfur compound produced by garlic plants (Allium sativum) upon tissue damage. Allicin exerts its strong antimicrobial activity against bacteria and fungi via S-thioallylation of protein thiols and low molecular weight thiols. Here, we investigated the effect of allicin on SARS-CoV-2 infected Vero E6 and Calu-3 cells. Toxicity tests revealed that Calu-3 cells showed greater allicin tolerance, probably due to >4-fold higher GSH levels compared to the very sensitive Vero E6 cells. Exposure of infected Vero E6 and Calu-3 cells to biocompatible allicin doses led to a ∼60–70% decrease of viral RNA and infectious viral particles. Label-free quantitative proteomics was used to investigate the changes in the Calu-3 proteome after SARS-CoV-2 infection and the effect of allicin on the host-virus proteome. SARS-CoV-2 infection of Calu-3 cells caused a strong induction of the antiviral interferon-stimulated gene (ISG) signature, including several antiviral effectors, such as cGAS, Mx1, IFIT, IFIH, IFI16, IFI44, OAS, and ISG15, pathways of vesicular transport, tight junctions (KIF5A/B/C, OSBPL2, CLTCL1, and ARHGAP17) and ubiquitin modification (UBE2L3/5), as well as reprogramming of host metabolism, transcription and translation. Allicin treatment of infected Calu-3 cells reduced the expression of IFN signaling pathways and ISG effectors and reverted several host pathways to levels of uninfected cells. Allicin further reduced the abundance of the structural viral proteins N, M, S and ORF3 in the host-virus proteome. In conclusion, our data demonstrate the antiviral and immunomodulatory activity of biocompatible doses of allicin in SARS-CoV-2-infected cell cultures. Future drug research should be directed to exploit the thiol-reactivity of allicin derivatives with increased stability and lower human cell toxicity as antiviral lead compounds.
Epithelial cells are an important line of defense within the lung. Disruption of the epithelial barrier by pathogens enables the systemic dissemination of bacteria or viruses within the host leading to severe diseases with fatal outcomes. Thus, the lung epithelium can be damaged by seasonal and pandemic influenza A viruses. Influenza A virus infection induced dysregulation of the immune system is beneficial for the dissemination of bacteria to the lower respiratory tract, causing bacterial and viral co-infection. Host cells regulate protein homeostasis and the response to different perturbances, for instance provoked by infections, by post translational modification of proteins. Aside from protein phosphorylation, ubiquitination of proteins is an essential regulatory tool in virtually every cellular process such as protein homeostasis, host immune response, cell morphology, and in clearing of cytosolic pathogens. Here, we analyzed the proteome and ubiquitinome of A549 alveolar lung epithelial cells in response to infection by either Streptococcus pneumoniae D39Δcps or influenza A virus H1N1 as well as bacterial and viral co-infection. Pneumococcal infection induced alterations in the ubiquitination of proteins involved in the organization of the actin cytoskeleton and Rho GTPases, but had minor effects on the abundance of host proteins. H1N1 infection results in an anti-viral state of A549 cells. Finally, co-infection resembled the imprints of both infecting pathogens with a minor increase in the observed alterations in protein and ubiquitination abundance.
Bloodstream infections caused by Streptococcus pneumoniae induce strong inflammatory and procoagulant cellular responses and affect the endothelial barrier of the vascular system. Bacterial virulence determinants, such as the cytotoxic pore-forming pneumolysin, increase the endothelial barrier permeability by inducing cell apoptosis and cell damage. As life-threatening consequences, disseminated intravascular coagulation followed by consumption coagulopathy and low blood pressure is described. With the aim to decipher the role of pneumolysin in endothelial damage and leakage of the vascular barrier in more detail, we established a chamber-separation cell migration assay (CSMA) used to illustrate endothelial wound healing upon bacterial infections. We used chambered inlets for cell cultivation, which, after removal, provide a cell-free area of 500 μm in diameter as a defined gap in primary endothelial cell layers. During the process of wound healing, the size of the cell-free area is decreasing due to cell migration and proliferation, which we quantitatively determined by microscopic live cell monitoring. In addition, differential immunofluorescence staining combined with confocal microscopy was used to morphologically characterize the effect of bacterial attachment on cell migration and the velocity of gap closure. In all assays, the presence of wild-type pneumococci significantly inhibited endothelial gap closure. Remarkably, even in the presence of pneumolysin-deficient pneumococci, cell migration was significantly retarded. Moreover, the inhibitory effect of pneumococci on the proportion of cell proliferation versus cell migration within the process of endothelial gap closure was assessed by implementation of a fluorescence-conjugated nucleoside analogon. We further combined the endothelial CSMA with a microfluidic pump system, which for the first time enabled the microscopic visualization and monitoring of endothelial gap closure in the presence of circulating bacteria at defined vascular shear stress values for up to 48 h. In accordance with our CSMA results under static conditions, the gap remained cell free in the presence of circulating pneumococci in flow. Hence, our combined endothelial cultivation technique represents a complex in vitro system, which mimics the vascular physiology as close as possible by providing essential parameters of the blood flow to gain new insights into the effect of pneumococcal infection on endothelial barrier integrity in flow.
Glutathione (GSH) was initially identified and characterized for its redox properties andlater for its contributions to detoxification reactions. Over the past decade, however, the essentialcontributions of glutathione to cellular iron metabolism have come more and more into focus. GSH isindispensable in mitochondrial iron-sulfur (FeS) cluster biosynthesis, primarily by co-ligating FeSclusters as a cofactor of the CGFS-type (class II) glutaredoxins (Grxs). GSH is required for the exportof the yet to be defined FeS precursor from the mitochondria to the cytosol. In the cytosol, it is anessential cofactor, again of the multi-domain CGFS-type Grxs, master players in cellular iron and FeStrafficking. In this review, we summarize the recent advances and progress in this field. The mosturgent open questions are discussed, such as the role of GSH in the export of FeS precursors frommitochondria, the physiological roles of the CGFS-type Grx interactions with BolA-like proteins andthe cluster transfer between Grxs and recipient proteins
Re-Establishment Techniques and Transplantations of Charophytes to Support Threatened Species
(2021)
Re-establishment of submerged macrophytes and especially charophyte vegetation is a common aim in lake management. If revegetation does not happen spontaneously, transplantations may be a suitable option. Only rarely have transplantations been used as a tool to support threatened submerged macrophytes and, to a much lesser extent, charophytes. Such actions have to consider species-specific life strategies. K-strategists mainly inhabit permanent habitats, are perennial, have low fertility and poor dispersal ability, but are strong competitors and often form dense vegetation. R-strategists are annual species, inhabit shallow water and/or temporary habitats, and are richly fertile. They disperse easily but are weak competitors. While K-strategists easily can be planted as green biomass taken from another site, rare R-strategists often must be reproduced in cultures before they can be planted on-site. In Sweden, several charophyte species are extremely rare and fail to (re)establish, though apparently suitable habitats are available. Limited dispersal and/or lack of diaspore reservoirs are probable explanations. Transplantations are planned to secure the occurrences of these species in the country. This contribution reviews the knowledge on life forms, dispersal, establishment, and transplantations of submerged macrophytes with focus on charophytes and gives recommendations for the Swedish project.
Certain pathogenic bacteria adopt an intracellular lifestyle and proliferate in eukaryotic host cells. The intracellular niche protects the bacteria from cellular and humoral components of the mammalian immune system, and at the same time, allows the bacteria to gain access to otherwise restricted nutrient sources. Yet, intracellular protection and access to nutrients comes with a price, i.e., the bacteria need to overcome cell-autonomous defense mechanisms, such as the bactericidal endocytic pathway. While a few bacteria rupture the early phagosome and escape into the host cytoplasm, most intracellular pathogens form a distinct, degradation-resistant and replication-permissive membranous compartment. Intracellular bacteria that form unique pathogen vacuoles include Legionella, Mycobacterium, Chlamydia, Simkania, and Salmonella species. In order to understand the formation of these pathogen niches on a global scale and in a comprehensive and quantitative manner, an inventory of compartment-associated host factors is required. To this end, the intact pathogen compartments need to be isolated, purified and biochemically characterized. Here, we review recent progress on the isolation and purification of pathogen-modified vacuoles and membranes, as well as their proteomic characterization by mass spectrometry and different validation approaches. These studies provide the basis for further investigations on the specific mechanisms of pathogen-driven compartment formation.
Escherichia coli has been commonly used as a platform for recombinant protein production and accounts for approximately 30% of current biopharmaceuticals on the market. Nowadays, many recombinant proteins require post-translational modifications which E. coli normally cannot facilitate. Therefore, novel technological advancements are unceasingly being developed to improve the E. coli expression system. In this work, some of the most recently engineered platforms for the production of disulfide bond-containing proteins were used to study the E. coli proteome under heterologous protein production stress. The effects of protein secretion via the Sec and Tat translocation pathways were examined using a comparative LC-MS/MS analysis. The E. coli proteome responds to foreign protein production by activation of several overlapping stress responses with a high degree of interaction. In consequence, a number of important cellular processes such as cellular metabolism, protein transport, redox state of the cytoplasm and membrane structure are altered by the production stress. These changes lead to the reduction of cellular growth and recombinant product yields. Resolving the identified bottlenecks will increase the efficiency of recombinant protein expression processes in E. coli.