Kenn Gerdes

Bio: Kenn Gerdes is an academic researcher from University of Copenhagen. The author has contributed to research in topics: Plasmid & Antitoxin. The author has an hindex of 78, co-authored 170 publications receiving 20524 citations. Previous affiliations of Kenn Gerdes include University of Newcastle & University of Southern Denmark.

Prokaryotic toxin-antitoxin stress response loci.

Abstract: Although toxin-antitoxin gene cassettes were first found in plasmids, recent database mining has shown that these loci are abundant in free-living prokaryotes, including many pathogenic bacteria. For example, Mycobacterium tuberculosis has 38 chromosomal toxin-antitoxin loci, including 3 relBE and 9 mazEF loci. RelE and MazF are toxins that cleave mRNA in response to nutritional stress. RelE cleaves mRNAs that are positioned at the ribosomal A-site, between the second and third nucleotides of the A-site codon. It has been proposed that toxin-antitoxin loci function in bacterial programmed cell death, but evidence now indicates that these loci provide a control mechanism that helps free-living prokaryotes cope with nutritional stress.

Toxin–antitoxin loci are highly abundant in free-living but lost from host-associated prokaryotes

Abstract: Prokaryotic chromosomes code for toxin-antitoxin (TA) loci, often in multiple copies. In E.coli, experimental evidence indicates that TA loci are stress-response elements that help cells survive unfavorable growth conditions. The first gene in a TA operon codes for an antitoxin that combines with and neutralizes a regulatory 'toxin', encoded by the second gene. RelE and MazF toxins are regulators of translation that cleave mRNA and function, in interplay with tmRNA, in quality control of gene expression. Here, we present the results from an exhaustive search for TA loci in 126 completely sequenced prokaryotic genomes (16 archaea and 110 bacteria). We identified 671 TA loci belonging to the seven known TA gene families. Surprisingly, obligate intracellular organisms were devoid of TA loci, whereas free-living slowly growing prokaryotes had particularly many (38 in Mycobacterium tuberculosis and 43 in Nitrosomonas europaea). In many cases, TA loci were clustered and closely linked to mobile genetic elements. In the most extreme of these cases, all 13 TA loci of Vibrio cholerae were bona fide integron elements located in the V.cholerae mega-integron. These observations strongly suggest that TA loci are mobile cassettes that move frequently within and between chromosomes and also lend support to the hypothesis that TA loci function as stress-response elements beneficial to free-living prokaryotes.

Recent functional insights into the role of (p)ppGpp in bacterial physiology

Abstract: The alarmones guanosine tetraphosphate and guanosine pentaphosphate (collectively referred to as (p) ppGpp) are involved in regulating growth and several different stress responses in bacteria. In ...

Mechanisms of bacterial persistence during stress and antibiotic exposure.

Abstract: BACKGROUND The escalating crisis of multidrug resistance is raising fears of untreatable infections caused by bacterial “superbugs.” However, many patients already suffer from infections that are effectively untreatable due to innate bacterial mechanisms for persistence. This phenomenon is caused by the formation of specialized persister cells that evade antibiotic killing and other stresses by entering a physiologically dormant state, irrespective of whether they possess genes enabling antibiotic resistance. The recalcitrance of persister cells is a major cause of prolonged and recurrent courses of infection that can eventually lead to complete antibiotic treatment failure. Regularly growing bacteria differentiate into persister cells stochastically at a basal rate, but this phenotypic conversion can also be induced by environmental cues indicative of imminent threats for the bacteria. Size and composition of the persister subpopulation in bacterial communities are largely controlled by stress signaling pathways, such as the general stress response or the SOS response, in conjunction with the second messenger (p)ppGpp that is almost always involved in persister formation. Consequently, persister formation is stimulated under conditions that favor the activation of these signaling pathways. Such conditions include bacterial biofilms and hostile host environments, as well as response to damage caused by sublethal concentrations of antibiotics. ADVANCES The limited comprehensive understanding of persister formation and survival is a critical issue in controlling persistent infections. However, recent work in the field has uncovered the molecular architecture of several cellular pathways underlying bacterial persistence, as well as the functional interactions that generate heterogeneous populations of persister cells. These results confirm the long-standing notion that persistence is intimately connected to slow growth or dormancy in the sense that a certain level of physiological quiescence is attained. Most prominently, the central role of toxin-antitoxin (TA) modules has been explained in considerable detail. In the model organism Escherichia coli K-12, two major pathways of persister formation via TA modules are both controlled by (p)ppGpp and involve toxin HokB and a panel of mRNA endonuclease toxins, respectively. Whereas activation of the membrane-associated toxin HokB depends on the enigmatic (GTPase) guanosine triphosphatase Obg and causes persister formation by abolishing the proton-motive force, mRNA endonuclease toxins are activated through antitoxin degradation by protease Lon and globally inhibit translation. In addition to these two pathways, toxin TisB is activated in response to DNA damage by the SOS response and promotes persister formation in a manner similar to HokB. Beyond TA modules, many additional factors (such as cellular energy metabolism or drug efflux) have been found to contribute to persister formation and survival, but their position in particular molecular pathways is often unclear. Altogether, this diversity of mechanisms drives the formation of a highly heterogeneous ensemble of persister cells that displays multistress and multidrug tolerance as the root of the recalcitrance of persistent infections. OUTLOOK Though recent advances in the field have greatly expanded our understanding of the molecular mechanisms underlying persister formation, important facets have remained elusive and should be addressed in future studies. One example is the upstream signaling input into the pathways mediating bacterial persister formation (e.g., the nature of the pacemaker driving stochastic persister formation). Similarly, it is often not well understood how—beyond the general idea of dormancy—persister cells can survive the action of lethal antibiotics. Finally, one curious aspect of the persister field is recurrent inconsistency between the results obtained by different groups. We speculate that these variations may be linked to subtle differences in experimental procedures inducing separate yet partially redundant pathways of persister formation. It is evident that the elucidation of this phenomenon may not only consolidate progress in the field but also offer the chance to gain insights into the molecular basis and control of bacterial persistence.

Unique type of plasmid maintenance function: postsegregational killing of plasmid-free cells.

Abstract: The stability locus parB+ of plasmid R1 has been found to specify a unique type of plasmid maintenance function. Two genes, hok (host killing) and sok (suppressor of killing), are required for the stabilizing activity. The hok gene encodes a highly toxic gene product, whose overexpression causes a rapid killing and a concomitant dramatic change in morphology of the host cell. The other gene, sok, was found to encode a product that counteracts the hok gene-mediated killing. The parB+ region was inserted in a plasmid with a temperature-sensitive replication system. At nonpermissive temperature, the parB+ plasmid was maintained in the population for a significantly longer period than the corresponding parB- plasmid. Coupled to this extended maintenance, a large fraction of the population was shown to be nonviable plasmid-free cells with the characteristic hok-induced change in morphology. Based on these findings, we propose that the parB+ locus mediates plasmid stability by killing cells that have lost the parB+ plasmid during the preceding cell division, thereby ensuring that a growing bacterial culture predominantly consists of plasmid-containing cells.

Construction of Escherichia coli K-12 in-frame, single-gene knockout mutants: the Keio collection.

Abstract: We have systematically made a set of precisely defined, single-gene deletions of all nonessential genes in Escherichia coli K-12. Open-reading frame coding regions were replaced with a kanamycin cassette flanked by FLP recognition target sites by using a one-step method for inactivation of chromosomal genes and primers designed to create in-frame deletions upon excision of the resistance cassette. Of 4288 genes targeted, mutants were obtained for 3985. To alleviate problems encountered in high-throughput studies, two independent mutants were saved for every deleted gene. These mutants-the 'Keio collection'-provide a new resource not only for systematic analyses of unknown gene functions and gene regulatory networks but also for genome-wide testing of mutational effects in a common strain background, E. coli K-12 BW25113. We were unable to disrupt 303 genes, including 37 of unknown function, which are candidates for essential genes. Distribution is being handled via GenoBase (http://ecoli.aist-nara.ac.jp/).

Tight regulation, modulation, and high-level expression by vectors containing the arabinose PBAD promoter.

Abstract: We have constructed a series of plasmid vectors (pBAD vectors) containing the PBAD promoter of the araBAD (arabinose) operon and the gene encoding the positive and negative regulator of this promoter, araC. Using the phoA gene and phoA fusions to monitor expression in these vectors, we show that the ratio of induction/repression can be 1,200-fold, compared with 50-fold for PTAC-based vectors. phoA expression can be modulated over a wide range of inducer (arabinose) concentrations and reduced to extremely low levels by the presence of glucose, which represses expression. Also, the kinetics of induction and repression are very rapid and significantly affected by the ara allele in the host strain. Thus, the use of this system which can be efficiently and rapidly turned on and off allows the study of important aspects of bacterial physiology in a very simple manner and without changes of temperature. We have exploited the tight regulation of the PBAD promoter to study the phenotypes of null mutations of essential genes and explored the use of pBAD vectors as an expression system.

Biofilms: an emergent form of bacterial life.

Abstract: Bacterial biofilms are formed by communities that are embedded in a self-produced matrix of extracellular polymeric substances (EPS). Importantly, bacteria in biofilms exhibit a set of 'emergent properties' that differ substantially from free-living bacterial cells. In this Review, we consider the fundamental role of the biofilm matrix in establishing the emergent properties of biofilms, describing how the characteristic features of biofilms - such as social cooperation, resource capture and enhanced survival of exposure to antimicrobials - all rely on the structural and functional properties of the matrix. Finally, we highlight the value of an ecological perspective in the study of the emergent properties of biofilms, which enables an appreciation of the ecological success of biofilms as habitat formers and, more generally, as a bacterial lifestyle.

Persister cells, dormancy and infectious disease

Abstract: Several well-recognized puzzles in microbiology have remained unsolved for decades. These include latent bacterial infections, unculturable microorganisms, persister cells and biofilm multidrug tolerance. Accumulating evidence suggests that these seemingly disparate phenomena result from the ability of bacteria to enter into a dormant (non-dividing) state. The molecular mechanisms that underlie the formation of dormant persister cells are now being unravelled and are the focus of this Review.