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Avian pathogenic Escherichia coli (APEC) represent a subset of the so-called extraintestinal pathogenic Escherichia coli (ExPEC) pathotype that can cause various extraintestinal infections in humans and animals. APEC are the causative agent of localized colibacillosis or systemic infection in poultry. In this latter case, the syndrome starts as an infection of the upper respiratory tract and develops into a systemic infection. Generally, ExPEC are characterized by a broad variety of virulence-associated factors that may contribute to pathogenesis. Major virulence factors, however, that clearly define this pathotype, have not been identified. Instead, virulence-associated genes of ExPEC and thus also of APEC could be used in a mix-and-match-fashion. Both pathotypes could not be clearly distinguished by molecular epidemiology, and this suggested a hypothetical zoonotic risk caused by APEC. Accordingly, the main scientific question of this study was to characterize common traits as well as differences of APEC and human ExPEC variants that could either support the possible zoonotic risk posed by these pathogenic E. coli strains or indicate factors involved in host specificity. Comparative genomic analysis of selected APEC and human ExPEC isolates of the same serotype indicated that these variants could not be clearly distinguished on the basis of (i) general phenotypes, (ii) phylogeny, (iii) the presence of typical ExPEC virulence genes, and (iv) the presence of pathoadaptive mutations. Allelic variations in genes coding for adhesins such as MatB and CsgA or their regulators MatA and CsgD have been observed, but further studies are required to analyze their impact on pathogenicity. On this background, the second part of this thesis focused on the analysis of differences between human ExPEC and APEC isolates at the gene expression level. The analysis of gene expression of APEC and human ExPEC under growth conditions that mimick their hosts should answer the question whether these bacterial variants may express factors required for their host-specificity. The transcriptomes of APEC strain BEN374 and human ExPEC isolate IHE3034 were compared to decipher whether there was a specific or common behavior of APEC and human ExPEC, in response to the different body temperatures of man (37°C) or poultry (41°C). Only a few genes were induced at 41 °C in each strain relative to growth at 37 °C. The group of down-regulated genes in both strains was markedly bigger and mainly included motility and chemotaxis genes. The results obtained from the transcriptome, genomic as well as phenotypic comparison of human ExPEC and APEC, supports the idea of a potential zoonotic risk of APEC and certain human ExPEC variants. In the third part of the thesis, the focus was set on the characterization of Mat fimbriae, and their potential role during ExPEC infection. Comparison of the mat gene cluster in K-12 strain MG1655 and O18:K1 isolate IHE3034 led to the discovery of differences in (i) DNA sequence, (ii) the presence of transcriptional start and transcription factor binding sites as well as (iii) the structure of the matA upstream region that account for the different regulation of Mat fimbriae expression in these strains. A negative role of the H-NS protein on Mat fimbriae expression was also proven at 20 °C and 37 °C by real-time PCR. A major role of this fimbrial adhesin was demonstrated for biofilm formation, but a significant role of Mat fimbriae for APEC in vivo virulence could not yet be determined. Interestingly, the absence of either a functional matA gene or that of the structural genes matBCDEF independently resulted in upregulation of motility in E. coli strains MG1655 and IHE3034 by a so far unknown mechanism. In conclusion, the results of this thesis indicate a considerable overlap between human and animal ExPEC strains in terms of genome content and phenotypes. It becomes more and more apparent that the presence of a common set of virulence-associated genes among ExPEC strains as well as similar virulence gene expression patterns and phylogenetic backgrounds indicate a significant zoonotic risk of avian-derived E. coli isolates. In addition, new virulence factors identified in human ExPEC may also play a role in the pathogenesis of avian ExPEC.
Cysteines play important roles in the biochemistry of many proteins. The high reactivity, redox properties, and ability of the free thiol group to coordinate metal ions designate cysteines as the amino acids of choice to form key catalytic components of many enzymes. Also, cysteines readily react with reactive oxygen and nitrogen species to form reversible oxidative thiol modifications. Over the last few years, an increasing number of proteins have been identified that use redox-mediated thiol modifications to modulate their function, activity, or localization. These redox-regulated proteins are central players in numerous important cellular processes. First aim of this study was to discover nitric oxide (NO) sensitive proteins in E. coli, whose redox-mediated functional changes might explain the physiological alterations observed in E. coli cells suffering from NO-stress. To identify E. coli proteins that undergo reversible thiol modifications upon NO-treatment in vivo, I applied a differential thiol trapping technique combined with two-dimensional gel analysis. 10 proteins were found to contain thiol groups sensitive to NO-treatment. Subsequent genetic studies revealed that the oxidative modifications of AceF & IlvC are, in part, responsible for the observed NO-induced growth inhibition. Noteworthy, the majority of identified protein targets turned out to be specifically sensitive towards reactive nitrogen species. This oxidant specificity was tested on one NO-sensitive protein, the small subunit of glutamate synthase. In vivo and in vitro activity studies demonstrated that glutamate synthase rapidly inactivates upon nitric oxide treatment but is resistant towards other oxidative stressors. These results imply that reactive oxygen and nitrogen species affect distinct physiological processes in bacteria. The second aim of my study was to identify redox-sensitive proteins in S. cerevisiae and to use their redox state as in vivo read-out to assess the role of oxidative stress during the eukaryotic aging process. I first determined the precise in vivo thiol status of almost 300 yeast proteins located in the cytosol and sub-cellular compartments of yeast cells using a highly quantitative mass spectrometry based thiol trapping technique, called OxICAT. The identified proteins can be clustered in four groups: 1) proteins, whose cysteine residues are oxidation resistant; 2) proteins with structurally or functionally important cysteine modifications 3) proteins with highly oxidation-sensitive active site cysteines, which are partially oxidized in exponentially growing yeast cells due to their exquisite sensitivity towards low amounts of ROS; 4) proteins that are reduced in exponentially growing cells but harbor redox-sensitive cysteine(s) that affect the catalytic function of the protein during oxidative stress. These oxidative stress sensitive proteins were identified by exposure of yeast cells to sublethal concentrations of H2O2 or superoxide. It was shown that the major targets of peroxide- and superoxide-mediated stress in the cell are proteins involved in translation, glycolysis, TCA cycle and amino acid biosynthesis. These targets indicate that cells rapidly redirect the metabolic flux and energy towards the pentose phosphate pathway in an attempt to ensure the production of the reducing equivalent NADPH to counterattack oxidative stress. These results reveal that the quantitative assessment of a protein’s oxidation state is a valuable tool to identify catalytically active and redox-sensitive cysteine residues. The OxICAT technology was then used to precisely determine extent and onset of oxidative stress in chronologically aging S. cerevisiae cells by utilizing the redox status of proteins as physiological read-out. I found that chronological aging yeast cells undergo a global collapse of the cellular redox homeostasis, which precedes cell death. The onset of this collapse appears to correlate with the yeast life span, as caloric restriction increases the life span and delays the redox collapse. These results suggest that maintenance of the redox balance might contribute to the life expanding benefits of regulating the caloric intake of yeast. Clustering analysis of all oxidatively modified proteins in chronological aging yeast revealed a subset of proteins whose oxidative thiol modifications significantly precede the general redox collapse. Oxidation of these early target proteins, which most likely results in a loss of their activity, might contribute to or even cause the observed loss of redox homeostasis (i.e., thioredoxin reductase) in chronologically aging yeast. These studies in aging yeast expand our understanding how changes in redox homeostasis affect the life span of yeast cells and confirm the importance of oxidative thiol modifications as key posttranslational modifications in pro- and eukaryotic organisms.
In this study pore forming proteins of the gram-negative bacteria B. burgdorferi, B. duttonii and E.coli were investigated. Therefore the study is subdivided into three parts. In the first part outer membrane preparation of three relapsing fever Borrelia were investigated. In the second part the putative TolC homologue BB0124 of B. burgdorferi, the Lyme borreliosis agent, was studied. In the last part the influence of point mutants within the greasy slide of the maltose specific porin (LamB) of E. coli were shown. In the first part of this study outer membrane preparations of three Borrelia relapsing fever strains have been studied for pore-forming activity in the black lipid bilayer assay. Histograms of conductance fluctuations were obtained from single-channel experiments with outer membrane preparations of B. hermsii, B. recurentis and B. duttonii. All strains had a different conductance fluctuation pattern with a broad range of single-channel conductance values varying from 0.5 nS – 11 nS. Common for all three strains was a high pore-forming activity at around 0.5 nS. Furthermore the proteins of the outer membrane of B. duttonii were separated by chromatographic methods. Some eluate fractions contained a channel-forming protein, which was forming stable channels with a single-channel conductance of 80 pS in 1 M KCl. Characterization of this channel showed that it is slightly anionic selective and voltage independent. The small single-channel conductance suggests that it is a specific pore. However, a substrate specificity could not be determined. In the second part, for the B. burgdorferi HB19 and p66 knock out strain HB19/K02, their outer membrane preparations were characterized in the black lipid bilayer assay. Comparing the histograms of single-channel conductions fluctuations of both strains showed no single-channel activity at 11.5 nS for the p66 knock out strain. This verifies earlier studies that P66 is a pore-forming protein in B. burgdorferi. Furthermore, one fraction obtained by anion exchange chromatography of the p66 knock out outer membrane protein preparation showed a uniform channel-forming activity with a single channel conductance of 300 pS. The electrophysically characterization of the 300 pS channel showed that it is not ionselective or voltage dependent. By mass spectrometry using peptide mass finger prints, BB0142 could be identified as the sole channel forming candidate in the active fraction. A BLAST search and a conserved domain search showed that BB0142 is a putative TolC homologue in B. burgdorferi. Furthermore the location of the bb0142 gene within the chromosome is in an operon encoding a multidrug efflux pump. In this study the expression of an outer membrane component of a putative drug efflux system of B. burgdorferi was shown for the first time. In the third part functional studies of the maltooligosaccharide-specific LamB channel were performed. The 3D-structure of LamB suggests that a number of aromatic residues (Y6, Y41, W74, F229, W358 and W420) within the channel lumen is involved in carbohydrate and ion transport. All aromatic residues were replaced by alanine (A) scanning mutagenesis. Furthermore, LamB mutants were created in which one, two, three, four and five aromatic residues were replaced to study their effects on ion and maltopentaose transport through LamB. The purified mutant proteins were reconstituted into lipid bilayer membranes and the single-channel conductance was studied. The results suggest that all aromatic residues provide some steric hindrance for ion transport through LamB. Highest impact is provided by Y6 and Y41, which are localized opposite to Y118, which forms the central constriction of the LamB channel. Stability constants for binding of maltopentaose to the mutant channels were measured using titration experiments with the carbohydrate. The mutation of one or several aromatic amino acids led to a substantial decrease of the stability constant of binding. The highest effect was observed when all aromatic amino acids were replaced by alanine because no binding of maltopentaose could be detected in this case. However, binding was again possible when Y118 was replaced by tryptophane (W). The carbohydrate-induced block of the channel function could also be used for the study of current noise through the different mutant LamB-channels. The analysis of the power density spectra of some of the mutants allowed the evaluation of the on- and off-rate constants (k1 and k-1) of carbohydrate binding to the binding-site inside the channels. The results suggest that both on- and off-rate constants were affected by the mutations. For most mutants k1 decreased and k-1 increased.
FinO-domain proteins represent an emerging family of RNA-binding proteins (RBPs) with diverse roles in bacterial post-transcriptional control and physiology. They exhibit an intriguing targeting spectrum, ranging from an assumed single RNA pair (FinP/traJ) for the plasmid-encoded FinO protein, to transcriptome-wide activity as documented for chromosomally encoded ProQ proteins. Thus, the shared FinO domain might bear an unusual plasticity enabling it to act either selectively or promiscuously on the same cellular RNA pool. One caveat to this model is that the full suite of in vivo targets of the assumedly highly selective FinO protein is unknown. Here, we have extensively profiled cellular transcripts associated with the virulence plasmid-encoded FinO in Salmonella enterica. While our analysis confirms the FinP sRNA of plasmid pSLT as the primary FinO target, we identify a second major ligand: the RepX sRNA of the unrelated antibiotic resistance plasmid pRSF1010. FinP and RepX are strikingly similar in length and structure, but not in primary sequence, and so may provide clues to understanding the high selectivity of FinO-RNA interactions. Moreover, we observe that the FinO RBP encoded on the Salmonella virulence plasmid controls the replication of a cohabitating antibiotic resistance plasmid, suggesting cross-regulation of plasmids on the RNA level.
In the last years more than one hundred microbial genomes have been sequenced, many of them from pathogenic bacteria. The availability of this huge amount of sequence data enormously increases our knowledge on the genome structure and plasticity, as well as on the microbial diversity and evolution. In parallel, these data are the basis for the scientific “revolution” in the field of industrial and environmental biotechnology and medical microbiology – diagnostics and therapy, development of new drugs and vaccines against infectious agents. Together with the genomic approach, other molecular biological methods such as PCR, DNA-chip technology, subtractive hybridization, transcriptomics and proteomics are of increasing importance for research on infectious diseases and public health. The aim of this work was to characterize the genome structure and -content of the probiotic Escherichia coli strain Nissle 1917 (O6:K5:H31) and to compare these data with publicly available data on the genomes of different pathogenic and non-pathogenic E. coli strains and other closely related species. A cosmid genomic library of strain Nissle 1917 was screened for clones containing the genetic determinants contributing to the successful survival in and colonization of the human body, as well as to mediate this strain’s probiotic effect as part of the intestinal microflora. Four genomic islands (GEI I-IVNissle 1917) were identifed and characterized. They contain many known fitness determinants (mch/mcm, foc, iuc, kps, ybt), as well as novel genes of unknown function, mobile genetic elements or newly identified putative fitness-contributing factors (Sat, Iha, ShiA-homologue, Ag43-homologues). All islands were found to be integrated next to tRNA genes (serX, pheV, argW and asnT, respectively). Their structure and chromosomal localization closely resembles those of analogous islands in the genome of uropathogenic E. coli strain CFT073 (O6:K2(?):H1), but they lack important virulence genes of uropathogenic E. coli (hly, cnf, prf/pap). Evidence for instability of GEI IINissle 1917 was given, since a deletion event in which IS2 elements play a role was detected. This event results in loss of a 30 kb DNA region, containing important fitness determinants (iuc, sat, iha), and therefore probably might influence the colonization capacity of Nissle 1917 strain. In addition, a screening of the sequence context of tRNA-encoding genes in the genome of Nissle 1917 was performed to identify genome wide potential integration sites of “foreign” DNA. As a result, similar “tRNA screening patterns” have been observed for strain Nissle 1917 and for the uropathogenic E. coli O6 strains (UPEC) 536 and CFT073. I. Summary 4 The molecular reason for the semi-rough phenotype and serum sensitivity of strain Nissle 1917 was analyzed. The O6-antigen polymerase-encoding gene wzy was identified, and it was shown that the reason for the semi-rough phenotype is a frame shift mutation in wzy, due to the presence of a premature stop codon. It was shown that the restoration of the O side-chain LPS polymerization by complementation with a functional wzy gene increased serumresistance of strain Nissle 1917. The results of this study show that despite the genome similarity of the E. coli strain Nissle 1917 with the UPEC strain CFT073, the strain Nissle 1917 exhibits a specific set of geno- and phenotypic features which contribute to its probiotic action. By comparison with the available data on the genomics of different species of Enterobacteriaceae, this study contributes to our understanding of the important processes such as horizontal gene transfer, deletions and rearrangements which contribute to genome diversity and -plasticity, and which are driving forces for the evolution of bacterial variants. At last, the fim, bcs and rfaH determinats whose expression contributes to the mutlicellular behaviour and biofilm formation of E. coli strain Nissle 1917 have been characterized.
Role of alpha-Hemolysin for the in vitro Phagocytosis and intracellular killing of Escherichia coli
(1989)
The_role of a-hemolysin for the elimination of Eschericbia coli by phagocyres in vitro was investigated using sets of isogenic strains which included wild-type a -hemolyric srrains, derived strains with a reduced production of a-hemolysin and derived nonhemolytic strains. Phagocyrosis and intracellular killing of the bacteria by human blood granulocytes or monocytes were measured using growth inhibition rechniques. a-hemolytic strains were phagocytosed and killed ro a Jesser extent than isogenic strains with a reduced production of o:hemoJysin and isogenic nonhemolytic strains. The results obrained with granulocyres were similar to rhose obtained with monocyres although the elimination of bacteria by monocytes was less than that by granulocytes. These resulcs strongJy suggest that production of ahemolysin is a means by which E. coli counteracrs the activity of phagocytes by injuring these cells with the toxin.
Like all other Salmonella typhimurium strains examined, the smooth variants SF1397 (L T2) and 1366 and also their semi-rough and rough derivatives are non-haemolytic. Nevertheless, two haemolysin (Hly) plasmids of E. coli belonging to the inc groups incFllI,lv (pSU316) and incIz (pHly152) were able to be introduced into these strains by conjugation and stably maintained. A considerable percentage of the Hly+ transconjugants obtained had lost parts of their O-side chains, a result of selection for the better recipient capability of « semi-rough» variants rather than the direct influence of the Hly+ plasmids themselves. In contrast to the incF1lI1V plasmid pSU316, which exhibited higher conjugation rates with rough recipients, the incIz plasmid pHly152 was accepted best by smooth strains. Transformation with cloned E. coli haemolysin (hly) determinant was inefficient ( <10-8) for smooth strains, but 102-103 times higher for rough recipients, and was increased by the use of Salmonella-modified DNA. The transform ants and transconjugants were relatively stable and showed the same haemolytic activity as the E. coli donor strains. The virulence of the Hly+ smooth, semi-rough and rough S. typhimurium strains was tested in two mouse models, and neither the mortality rate nor the ability to multiply within the mouse spleen was influenced by the hly determinants.
The genetic determinant coding for the Pspecific F8 fimbriae was cloned from · the chromosome of the Escherichia coli wild-type strain 2980 (018: K5: H5: FlC, F8). The F8 determinant was further subcloned into the Pstl site of pBR322 and a restriction map was established. In a Southern hybridization experiment identity between the chromosomally encoded F8 determinant of 2980 and its cloned Counterpart was demonstrated. The cloned F8 fimbriäe and those of the wild type strain consist of a protein subunit of nearly 20 kDa. F8 fimbriated strains were agglutinated by an F8 polyclonal antiserum, caused mannose-resistant hemagglutination and attached to human uroepi thellal cells. The cloned F8 determinant was weil expressed in a variety of host strains.
E. coli strain 536 (06: K15: H31) isolated from a case of acute pyelonephritis, expresses S-fimbrial adhesins, P-related fimbriae, common type I fimbriae, and hemolysins. The respective chromosomally encoded determinants were cloned by constructing a genomic library of this strain. Furthermore, the strain produces the iron uptake substance, enterocheline, damages HeLa cells, and behaves in a serum-resistant mode. Genetic analysis of spontaneously arising non-hemolytic variants revealed that some of the virulence genes were physically linked to large unstable DNA regions, termed "pathogenicity islands", which were mapped in the respective positions on the E. coli K-12linkage map. By comparing the wild type strain and mutants in in vitro and in vivo assays, virulence features have been evaluated. In addition, a regulatory cross talk between adhesin determinants was found for the wild-type isolate. This particular mode of virulence regulation is missing in the mutant strain.
E. coli stcains isolated from patients with urinary tcact infecrions (UTn very often possess mannose"sensitive (MS) and mannose-resistant (MR) adherence facmrs (fimbriae). According to their receptor specificity the mannose-resistant adhesins can be divided inm several types, P, S, M and X. We have cloned rhe determinants of rhree groups of UTI E. coli adhesins, MS, p and S, and prepared specific aorisera against the fimbriae antigens. 189 hernagglutination (HA+) -positive stcains, 96 fecal isolates and 93 strains isoJated from UTI . have been tesred with rhese specific antisera and further characterized by receptor specific : HA, HA parteras and further of rhe "common 0 serogroups" 01, 02, 04, 06, 07, 08, 018, ' 025, 075, most prevalenr in UTI, and hemolysin production. · 68 (73 %) of the UTI srrains a.nd 50 (52%) of the fecal isolates showed P-receptor specificiry; 16 (17%) of the uropathogenic bacteria and 33 (34%) of the fecal strains exhibited S, M or X-fimbriae antigens. 24% of rhe P-hemagglutinating (P+) strains reacted wirb P (F8)-specific antiserum. In contrast, more than three quaner of the s+-srrains were agglutinated by S-specific antiserum. HA-pattern VJ and 018 amigen were found to be associared with P-fimbriae strains, wbereas HA-pattern V and VII and the 0 anrigens 02 (M-type), 06 and 018 (5-type) occurred most frequently in p- -strains. A high percentage of P-fimbriated strains showed mannose-sensitive hemagglurination and hemolysin production.
Isolation and characterization of coliphage Omega18A specific for Escherichia coli O18ac strains
(1987)
The bactedophage Q18A, specific for Escherichia coli 018ac srrains, was isolated frorn sewage. The results of host range and conjugation experiments showed that the sensitivity of bacteria to the phage is associated with rhe presence of 018ac antigens. With sorne of rhe 018 strains rhe phage Q18A produces clear Iysis on bacterial lawns only when applied at a high multiplicity and moreover the phage does not multiply. With rhe help of the phage Ql8A, E. coli 0 18ac strains could be divided inro rwo serologically clistinct subgroups called 018A and 018A1• E. coli strains belanging to the sugroup 0 ISAare sensitive to phage Q t8A wheteas bacteria of subgroup A1 are resistanr.
Background
Increasing bacterial resistance to antibiotics is a serious problem worldwide. We sought to record the acquisition of antibiotic-resistant Escherichia coli (E. coli) in healthy infants in Northern Thailand and investigated potential determinants.
Methods
Stool samples from 142 infants after birth, at ages 2wk, 2mo, 4 to 6mo, and 1y, and parent stool samples were screened for E. coli resistance to tetracycline, ampicillin, co-trimoxazole, and cefazoline by culture, and isolates were further investigated for multiresistance by disc diffusion method. Pulsed-field gel electrophoresis was performed to identify persistent and transmitted strains. Genetic comparison of resistant and transmitted strains was done by multilocus sequence typing (MLST) and strains were further investigated for extra- and intra-intestinal virulence factors by multiplex PCR.
Results
Forty-seven (33%) neonatal meconium samples contained resistant E. coli. Prevalence increased continuously: After 1y, resistance proportion (tetracycline 80%, ampicillin 72%, co-trimoxazole 66%, cefazoline 35%) almost matched those in parents. In 8 infants (6%), identical E. coli strains were found in at least 3 sampling time points (suggesting persistence). Transmission of resistant E. coli from parents to child was observed in only 8 families. MLST showed high diversity. We could not identify any virulence genes or factors associated with persistence, or transmission of resistant E. coli. Full-term, vaginal birth and birth in rural hospital were identified as risk factors for early childhood colonization with resistant E. coli.
Conclusion
One third of healthy Thai neonates harboured antibiotic-resistant E. coli in meconium. The proportion of resistant E. coli increased during the first year of life almost reaching the value in adults. We hypothesize that enhancement of infection control measures and cautious use of antibiotics may help to control further increase of resistance.
Complex formation between macromolecules constitutes the foundation of most cellular processes. Most known complexes are made up of two or more proteins interacting in order to build a functional entity and therefore enabling activities which
the single proteins could otherwise not fulfill. With the increasing knowledge about
noncoding RNAs (ncRNAs) it has become evident that, similar to proteins, many of
them also need to form a complex to be functional. This functionalization is usually executed by specific or global RNA-binding proteins (RBPs) that are specialized
binders of a certain class of ncRNAs. For instance, the enterobacterial global RBPs
Hfq and ProQ together bind >80 % of the known small regulatory RNAs (sRNAs),
a class of ncRNAs involved in post-transcriptional regulation of gene expression.
However, identification of RNA-protein interactions so far was performed individually by employing low-throughput biochemical methods and thereby hindered the discovery of such interactions, especially in less studied organisms such
as Gram-positive bacteria. Using gradient profiling by sequencing (Grad-seq), the
present thesis aimed to establish high-throughput, global RNA/protein complexome resources for Escherichia coli and Streptococcus pneumoniae in order to provide a
new way to investigate RNA-protein as well as protein-protein interactions in these
two important model organisms.
In E. coli, Grad-seq revealed the sedimentation profiles of 4,095 (∼85 % of
total) transcripts and 2,145 (∼49 % of total) proteins and with that reproduced
its major ribonucleoprotein particles. Detailed analysis of the in-gradient distribution of the RNA and protein content uncovered two functionally unknown
molecules—the ncRNA RyeG and the small protein YggL—to be ribosomeassociated. Characterization of RyeG revealed it to encode for a 48 aa long, toxic protein that drastically increases lag times when overexpressed. YggL was shown to
be bound by the 50S subunit of the 70S ribosome, possibly indicating involvement
of YggL in ribosome biogenesis or translation of specific mRNAs.
S. pneumoniae Grad-seq detected 2,240 (∼88 % of total) transcripts and 1,301
(∼62 % of total) proteins, whose gradient migration patterns were successfully reconstructed, and thereby represents the first RNA/protein complexome resource
of a Gram-positive organism. The dataset readily verified many conserved major
complexes for the first time in S. pneumoniae and led to the discovery of a specific
interaction between the 3’!5’ exonuclease Cbf1 and the competence-regulating ciadependent sRNAs (csRNAs). Unexpectedly, trimming of the csRNAs by Cbf1 stabilized the former, thereby promoting their inhibitory function. cbf1 was further shown
to be part of the late competence genes and as such to act as a negative regulator of
competence.
DNA hybridization experiments demonstrated that the gene clusters encoding the F8 fimbriae (fei) as well as the type I fimbriae (pi/) exist in a single copy on the chromosome of E. coli 018:K5 strain 2980. In conjugation experiments with appropriate donors, the chromosomal site of these gene clusters was determined. The pil genes were mapped close to the gene clusters thr and Jeu controlling the biosynthesis of threonine and leucine, respectively. The fei genes were found to be located close to the galactose operon (gal) between the position 17 and 21 of the E. coli chromosomallinkage map.
The reversibility of bacterial resistance to antibiotics is poorly understood. Therefore, the aim of this study was to determine, over a period of five years, the effect of fluoroquinolone (FQ) use in primary care on the development and gradual decay of Escherichia coli resistance to FQ. In this matched case–control study, we linked three sources of secondary data of the Health Service of the Autonomous Province of Bolzano, Italy. Cases were all those with an FQ-resistant E. coli (QREC)-positive culture from any site during a 2016 hospital stay. Data were analyzed using conditional logistic regression. A total of 409 cases were matched to 993 controls (FQ-sensitive E. coli) by the date of the first isolate. Patients taking one or more courses of FQ were at higher risk of QREC colonization/infection. The risk was highest during the first year after FQ was taken (OR 2.67, 95%CI 1.92–3.70, p < 0.0001), decreased during the second year (OR 1.54, 95%CI 1.09–2.17, p = 0.015) and became undetectable afterwards (OR 1.09, 95%CI 0.80–1.48, p = 0.997). In the first year, the risk of resistance was highest after greater cumulative exposure to FQs. Moreover, older age, male sex, longer hospital stays, chronic obstructive pulmonary disease (COPD) and diabetes mellitus were independent risk factors for QREC colonization/infection. A single FQ course significantly increases the risk of QREC colonization/infection for no less than two years. This risk is higher in cases of multiple courses, longer hospital stays, COPD and diabetes; in males; and in older patients. These findings may inform public campaigns and courses directed to prescribers to promote rational antibiotic use.
High-throughput sequencing (HTS) has revolutionized bacterial genomics. Its unparalleled sensitivity has opened the door to analyzing bacterial evolution and population genomics, dispersion of mobile genetic elements (MGEs), and within-host adaptation of pathogens, such as Escherichia coli.
One of the defining characteristics of intestinal pathogenic E. coli (IPEC) pathotypes is a specific repertoire of virulence factors (VFs). Many of these IPEC VFs are used as typing markers in public health laboratories to monitor outbreaks and guide treatment options. Instead, extraintestinal pathogenic E. coli (ExPEC) isolates are genotypically diverse and harbor a varied set of VFs -- the majority of which also function as fitness factors (FFs) for gastrointestinal colonization.
The aim of this thesis was the genomic characterization of pathogenic and commensal E. coli with respect to their virulence- and antibiotic resistance-associated gene content as well as phylogenetic background. In order to conduct the comparative analyses, I created a database of E. coli VFs, ecoli_VF_collection, with a focus on ExPEC virulence-associated proteins (Leimbach, 2016b). Furthermore, I wrote a suite of scripts and pipelines, bac-genomics-scripts, that are useful for bacterial genomics (Leimbach, 2016a). This compilation includes tools for assembly and annotation as well as comparative genomics analyses, like multi-locus sequence typing (MLST), assignment of Clusters of Orthologous Groups (COG) categories, searching for protein homologs, detection of genomic regions of difference (RODs), and calculating pan-genome-wide association statistics.
Using these tools we were able to determine the prevalence of 18 autotransporters (ATs) in a large, phylogenetically heterogeneous strain panel and demonstrate that many AT proteins are not associated with E. coli pathotypes. According to multivariate analyses and statistics the distribution of AT variants is instead significantly dependent on phylogenetic lineages. As a consequence, ATs are not suitable to serve as pathotype markers (Zude et al., 2014).
During the German Shiga toxin-producing E. coli (STEC) outbreak in 2011, the largest to date, we were one of the teams capable of analyzing the genomic features of two isolates. Based on MLST and detection of orthologous proteins to known E. coli reference genomes the close phylogenetic relationship and overall genome similarity to enteroaggregative E. coli (EAEC) 55989 was revealed. In particular, we identified VFs of both STEC and EAEC pathotypes, most importantly the prophage-encoded Shiga toxin (Stx) and the pAA-type plasmid harboring aggregative adherence fimbriae. As a result, we could show that the epidemic was caused by an unusual hybrid pathotype of the O104:H4 serotype. Moreover, we detected the basis of the antibiotic multi-resistant phenotype on an extended-spectrum beta-lactamase (ESBL) plasmid through comparisons to reference plasmids. With this information we proposed an evolutionary horizontal gene transfer (HGT) model for the possible emergence of the pathogen (Brzuszkiewicz et al., 2011).
Similarly to ExPEC, E. coli isolates of bovine mastitis are genotypically and phenotypically highly diverse and many studies struggled to determine a positive association of putative VFs. Instead the general E. coli pathogen-associated molecular pattern (PAMP), lipopolysaccharide (LPS), is implicated as a deciding factor for intramammary inflammation. Nevertheless, a mammary pathogenic E. coli (MPEC) pathotype was proposed presumably encompassing strains more adapted to elicit bovine mastitis with virulence traits differentiating them from commensals.
We sequenced eight E. coli isolates from udder serous exudate and six fecal commensals (Leimbach et al., 2016). Two mastitis isolate genomes were closed to a finished-grade quality (Leimbach et al., 2015). The genomic sequence of mastitis-associated E. coli (MAEC) strain 1303 was used to elucidate the biosynthesis gene cluster of its O70 LPS O-antigen. We analyzed the phylogenetic genealogy of our strain panel plus eleven bovine-associated E. coli reference strains and found that commensal or MAEC could not be unambiguously allocated to specific phylogroups within a core genome tree of reference E. coli. A thorough gene content analysis could not identify functional convergence of either commensal or MAEC, instead both have only very few gene families enriched in either pathotype. Most importantly, gene content and ecoli_VF_collection analyses showed that no virulence determinants are significantly associated with MAEC in comparison to bovine fecal commensals, disproving the MPEC hypothesis. The genetic repertoire of bovine-associated E. coli, again, is dominated by phylogenetic background. This is also mostly the case for large virulence-associated E. coli gene cluster previously associated with mastitis. Correspondingly, MAEC are facultative and opportunistic pathogens recruited from the bovine commensal gastrointestinal microbiota (Leimbach et al., 2017). Thus, E. coli mastitis should be prevented rather than treated, as antibiotics and vaccines have not proven effective.
Although traditional E. coli pathotypes serve a purpose for diagnostics and treatment, it is clear that the current typing system is an oversimplification of E. coli's genomic plasticity. Whole genome sequencing (WGS) revealed many nuances of pathogenic E. coli, including emerging hybrid or heteropathogenic pathotypes. Diagnostic and public health microbiology need to embrace the future by implementing HTS techniques to target patient care and infection control more efficiently.
The search for new antibiotics against multidrug-resistant (MDR), Gram-negative bacteria is crucial with respect to filling the antibiotics development pipeline, which is subject to a critical shortage of novel molecules. Screening of natural products is a promising approach for identifying antimicrobial compounds hosting a higher degree of novelty. Here, we report the isolation and characterization of four galloylglucoses active against different MDR strains of Escherichia coli and Klebsiella pneumoniae. A crude acetone extract was prepared from Paeonia officinalis Linnaeus leaves, and bioautography-guided isolation of active compounds from the extract was performed by liquid–liquid extraction, as well as open column, flash, and preparative chromatographic methods. Isolated active compounds were characterized and elucidated by a combination of spectroscopic and spectrometric techniques. In vitro antimicrobial susceptibility testing was carried out on E. coli and K. pneumoniae using 2 reference strains and 13 strains hosting a wide range of MDR phenotypes. Furthermore, in vivo antibacterial activities were assessed using Galleria mellonella larvae, and compounds 1,2,3,4,6-penta-O-galloyl-β-d-glucose, 3-O-digalloyl-1,2,4,6-tetra-O-galloyl-β-d-glucose, 6-O-digalloyl-1,2,3,4-tetra-O-galloyl-β-d-glucose, and 3,6-bis-O-digalloyl-1,2,4-tri-O-galloyl-β-d-glucose were isolated and characterized. They showed minimum inhibitory concentration (MIC) values in the range of 2–256 µg/mL across tested bacterial strains. These findings have added to the number of known galloylglucoses from P. officinalis and highlight their potential against MDR Gram-negative bacteria.
S fimbriae are able to recognize receptor molecules containing sialic acid and are produced by pathogenic E. coli strains causing urinary tract infection and menigitis. In order to characterize the corresponding genetic determinant, termed S fimbrial adhesin ( sfa) gene duster, we have cloned the S-specific genes from a urinary pathogen and from a meningitis isolate. Nine genes are involved in the production of S fimbriae, two of these, sfaB and sfaC code for regulatory proteins being necessary for the expression of S fimbriae. Two promoters, PB and Pc, are located in front of these genes. Transcription of the sfa determinant is influenced by activation of the promotersvia SfaB and SfaC, the action of the H-NS protein and an RNaseE-specific mRNA processing. In addition, a third promoter, P A• located in front of the major subunit gene sfaA, can be activated under special circumstances. Four genes of the sfa determinant code for the subunit-specific proteins, SfaA (16 kda), SfaG (17 kda), SfaS (14 kda) and SfaH (29 kda). It was demonstrated that the protein SfaA is the major subunit protein while SfaS is identical to the sialic-acid-specific adhesin of S fimbriae. The introduction of specific mutations into sfaS revealed that a region of six amino acids of the adhesin which includes two lysine and one arginine residues is involved in the receptor specific interaction of S fimbriae. Additionally, it has been shown that SfaS is necessary for the induction of fimbriation while SfaH plays a role in the stringency of binding of S fimbriae to erythrocytes.
We analyzed an Escherichia coli strain which harbours a chromosomal mutation that blocks the hemolysin excretion. Compartmentation studies showed that hemolysin accumulates in the cytoplasm and not in the periplasm. The mutation did not affect the SDS-PAGE protein pattern of the outer membrane, although some alterations were apparent in the periplasmic protein pattern. The mutant strain, E. coli Hsb-1 also failed to export a cloned fimbrial adhesin. The mutation maps in the min. 3.5 of the E. coli genetic map.
In this study, the role of histone-like proteins in gene regulation in uropathogenic Escherichia coli isolate 536 was monitored. The histone-like nucleoid structuring protein H-NS is a global regulator in Escherichia coli that has been intensively studied in non-pathogenic strains. No comprehensive study on the role of H-NS and it’s homolog StpA on gene expression in a pathogenic E. coli strain has been carried out so far. Moreover, we identified a third, so far uncharacterized member of the H-NS-like protein family in uropathogenic E. coli isolate 536, which was designated Hlp (H-NS-like protein). Hlp is a 134-amino acid protein, which shares 58 % sequence identity with H-NS. The gene coding for the Hlp protein, hlp, is found in several uropathogenic E. coli variants, but not in non-pathogenic E. coli K-12. In UPEC strains 536 and CFT073, Hlp is encoded on a possibly horizontally acquired 23-kb genomic region inserted into the serU locus. Studies on hlp transcription revealed, that the gene is transcribed monocistronically from a single promoter and that expression is repressed by H-NS. Purified Hlp protein was binding to its own and to the hns promoter, thereby mediating negative auto- and crossregulation. Furthermore, Hlp and H-NS were directly interacting, resulting in the formation of stable heteromers. Complementation studies with hns mutant strains in a K-12 background revealed that the Hlp protein had in vivo activity, being able to complement the lack of H-NS in terms of motility, growth, and repression of the proU, bgl, and clyA genes. When analyzing the role of the histone-like proteins in expression of virulence-associated genes by using DNA arrays and classical phenotypic assays, most of the observed effects were mediated by the H-NS protein alone. Expression profiling revealed that transcript level of more than 500 genes was affected by an hns mutation, resulting in increased expression of alpha-hemolysin, fimbriae and iron-uptake systems, as well as genes involved in stress adaptation. Furthermore, several other putative virulence factors were found to be part of the H-NS regulon. On the other hand, no effect of StpA alone was observed. An hns stpA double mutant, however, exhibited a distinct gene expression pattern that differed in great parts from that of the hns single mutant. This suggests a direct interaction between the two homologs and the existence of distinct regulons of H-NS and an H-NS/StpA heteromeric complex. Although the H-NS protein has – either as homomer or in complex with StpA – a marked impact on gene expression in pathogenic E. coli strains, its effect on urovirulence is ambiguous. At a high infection dose, hns mutants accelerate lethality in murine UTI and sepsis models relative to the wild type, probably due to increased production of alpha-hemolysin. At lower infectious dose, however, mutants lacking H-NS are attenuated through their impaired growth rate, which can only partially be compensated by the higher expression of numerous virulence factors. As seen with StpA, an hlp single mutant did not exhibit a notable phenotype under standard growth conditions. A severe growth defect of hns hlp double mutants at low temperatures, however, suggests a biological relevance of H-NS/Hlp heteromers under certain circumstances. Furthermore, these mutants expressed more capsular polysaccharide and curli fimbriae, thereby indicating a distinct role of H-NS and Hlp in regulation of these surface structures. The H-NS paralogs Hlp and StpA also modulated H-NS-mediated regulation of fimbrial adhesins, and are oppositely required for normal growth at low or high temperatures, respectively. Finally, expression levels of the three histone-like proteins H-NS, StpA and Hlp itself varied with different temperatures, thereby suggesting a flexible composition of the nucleoid-associated protein pool. Hence, we propose that the biological role of Hlp and StpA does not rely on a distinct function of the single protein, but rather on their interaction with the global regulator H-NS.