Project description:Nitrogenases are the only enzymes able to ‘fix’ gaseous nitrogen into bioavailable ammonia and, hence, are essential for sustaining life. Catalysis by nitrogenases requires both a large amount of ATP and electrons donated by strongly reducing ferredoxins or flavodoxins. Our knowledge about the mechanisms of electron transfer to nitrogenase enzymes is limited, with electron transport to the iron (Fe)-nitrogenase having hardly been investigated. Here, we characterised the electron transfer pathway to the Fe-nitrogenase in Rhodobacter capsulatus via proteome analyses, genetic deletions, complementation studies and phylogenetics. Proteome analyses revealed an upregulation of four ferredoxins under nitrogen-fixing conditions reliant on the Fe-nitrogenase in a molybdenum nitrogenase knockout strain (nifD), compared to non-nitrogen-fixing conditions. Based on these findings, R. capsulatus strains with deletions of ferredoxin (fdx) and flavodoxin (fld, nifF) genes were constructed to investigate their roles in nitrogen fixation by the Fe-nitrogenase. R. capsulatus deletion strains were characterised by monitoring diazotrophic growth and nitrogenase activity in vivo. Only deletion of fdxC or fdxN resulted in slower growth and reduced Fe-nitrogenase activity, whereas the double-deletion of both fdxC and fdxN abolished diazotrophic growth. Differences in the proteomes of ∆fdxC and ∆fdxN strains, in conjunction with differing plasmid complementation behaviours of fdxC and fdxN, indicate that the two Fds likely possess different roles and functions. These findings will guide future engineering of the electron transport systems to nitrogenase enzymes, with the aim of increased electron flux and product formation.

Project description:The transcriptional antisilencer VirB acts as a master regulator of virulence gene expression in the human pathogen Shigella flexneri. It binds defined sequences (virS) upstream of VirB-dependent promoters and counteracts their silencing by the nucleoid-organizing protein H-NS. However, its precise mode of action remains unclear. Notably, VirB is not a classical transcription factor but related to DNA partitioning pro- teins of the ParB family, which have recently been recognized as DNA-sliding clamps using CTP binding and hydrolysis to control their DNA entry gate. Here, we show that VirB binds CTP, embraces DNA in a clamp-like fashion upon its CTP-dependent loading at virS sites and slides laterally on DNA after clamp closure. Mutations that prevent CTP binding block the loading of VirB clamps in vitro and the formation of VirB nucleoprotein complexes in vivo. Thus, VirB represents a CTP-dependent molecular switch that uses a loading-and-sliding mechanism to control transcription during bacterial pathogenesis.

Project description:On-demand biomanufacturing has the potential to improve healthcare and self- sufficiency during space missions. Cell-free transcription and translation reactions combined with DNA blueprints can produce promising therapeutics like bacteriophages and virus-like particles. However, how space conditions affect the synthesis and self-assembly of such complex multi- protein structures is unknown. Here, we characterize the cell-free production of infectious bacteriophage T7 virions under simulated microgravity. Rotation in a 2D-clinostat increased the number of infectious particles compared to static controls. Quantitative analyses by mass spectrometry, immuno-dot-blot and real-time PCR showed no significant differences in protein and DNA contents, suggesting enhanced self-assembly of T7 phages in simulated microgravity. While the effects of genuine space conditions on the cell-free synthesis and assembly of bacteriophages remain to be investigated, our findings support the vision of a cell-free synthesis-enabled “astropharmacy”.

Project description:Secretion systems are used as weapons by a variety of Gram-negative bacteria. Among them the Type VI Secretion System (T6SS) gained more interest throughout the last years. The system functions as a molecular nano-weapon: it is used in inter-kingdom competition by various bacteria to deliver toxic effectors in target cells. Here we describe the role of the T6SS in Photorhabdus laumondii subsp. laumondii strain DJC, an entomopathogenic biocontrol agent able to live in different environmental niches, such as in symbiosis with nematodes and in the rhizosphere on plant roots. Using bioinformatic and protein motif analyses we identified four T6SS gene clusters (T6SS-1, T6SS-2, T6SS-3 and T6SS-4) and multiple orphan T6SS related genes in the genome of P. laumondii. Furthermore, we highlighted 11 T6SS effector-immunity pairs, including three undescribed membrane disrupting effectors, each with putatively different antibacterial activities. By label-free mass spectrometry of P. laumondii wild type cells and respective T6SS-deficient strains, we could point out a cross-link between T6SS and other Photorhabdus’ virulence related mechanisms such as PVCs, T3SS and pyocins. Furthermore, a change in motility as well as in the secondary metabolism was observed upon T6SS-deficiency. Here, we shed light on the T6SS in P. laumondii DJC and suggesting a cross-link of various virulence mechanisms, which could help to gain knowledge on T6SS and better figure out the Photorhabdus ability to live in polymicrobial environments.

Project description:Metabolism is fundamental to life, all life activities are sustained through metabolism. Metabolic engineering, while modifying host endogenous metabolic network or introducing heterologous pathway for biotechnological applications, often results in unfitness and suboptimal characteristics, because of the lack of full knowledge on host metabolism. Adaptive laboratory evolution (ALE), harnessing the nature of life -- evolution, has become a potent approach in phenotype optimization, environmental adaptation, and cell biology study1–3. Through ALE, alternative pathways of β-alanine biosynthesis4, pyridoxal 5’-phosphate (PLP) biosynthesis5, isoleucine biosynthesis6, as well as ATP generation7 have been uncovered; E. coli aerobic citrate utilization8,9 and various synthetic C1-trophy10–14 have been realized. In this study, we describe E. coli recruits the same workforce, Sad, in evolution through various strategies, i.e., catalytic efficiency improvement, gene dose increase, and gene expression regulations, to overcome metabolic damages (Fig. 1). Sad, i.e. NAD(P)+-dependent succinate semialdehyde dehydrogenase (SSADH), is an aldehyde dehydrogenase (ALDH) family protein. Sad oxidizes succinate semialdehyde to succinate, preventing accumulation of the toxic aldehyde intermediate in nitrogen metabolism, such as putrescine, arginine and γ-aminobutyrate (GABA) degradations15–17. Some bacteria, for example E. coli, possess also a NADP+-dependent SSADH, GabD15,18. SSADH is ubiquitous in both prokaryotes and eukaryotes. In human, it involves in catabolism of GABA, a major neurotransmitter, its malfunction leads to a disorder SSADH deficiency19. In plants, SSADH involves in leaf development and morphogenesis20 as well as defense of abiotic stress21. And in cyanobacteria, SSADH is an essential enzyme of its uncanonical tricarboxylic acid cycle. SSADH was also found to be able to oxidize glutarate semialdehyde, participating in lysine catabolism in bacteria.

Project description:The bacterial type III secretion system, also called injectisome, translocates effector proteins into eukaryotic target cells through a hollow needle that is anchored in the bacterial membranes. The recruitment of effector proteins to the machinery and the resulting export hierarchy involve the sorting platform, a conserved set of interacting proteins at the cytosolic interface of the injectisome. To gain insight into these processes, we localized and measured the movement of different functional fluorescently labeled sorting platform components in live Yersinia enterocolitica. The sorting platform proteins were part of ~5.1 and ~17.9 injectisomes per bacterium under non-secreting and secreting conditions, respectively. However, they also displayed a considerable mobile cytosolic pool. Using single particle tracking photoactivated localization microscopy, we were able to show the interaction of different components of the sorting platform with effector proteins in the cytosol of live bacteria. We found that effector proteins directly bind to the sorting platform proteins SctQ and SctL. In wild-type bacteria these proteins form larger cytosolic protein complexes involving the ATPase SctN and the membrane connector SctK. The mobility and composition of these complexes is modulated in presence of effector proteins and their chaperones, and upon initiation of secretion, which additionally leads to the emergence of large soluble complexes. Our quantitative data supports an effector shuttling mechanism, in which sorting platform protein bind to effectors in the cytosol and deliver the cargo to the export gate at the membrane-bound injectisome.

Project description:Phenotypic heterogeneity in bacteria results from stochastic processes or deterministic genetic programs. These deterministic programs often incorporate the versatile second messenger c-di-GMP, and by deploying c-di-GMP metabolizing enzyme(s) asymmetrically during cell division give rise to daughter cells with different c-di-GMP levels. Here, we identify a deterministic c-di-GMP-dependent genetic program that is hardwired into the cell cycle of Myxococcus xanthus to minimize cellular heterogeneity and guarantee the formation of phenotypically similar daughter cells during division. Cells lacking the diguanylate cyclase DmxA have an aberrant motility behaviour. DmxA is recruited to the cell division site and its activity switched on during cytokinesis, resulting in a dramatic but transient increase in the c-di-GMP concentration. During cytokinesis, this c-di-GMP burst ensures the symmetric incorporation and allocation of structural motility proteins and motility regulators at the new cell poles of the two daughters, thereby generating mirror-symmetric, phenotypically similar daughters with correct motility behaviours. These findings suggest a general c-di-GMP-dependent mechanism for minimizing cellular heterogeneity, and demonstrate that bacteria by deploying c-di-GMP metabolizing enzymes to distinct subcellular locations ensure the formation of dissimilar or similar daughter cells.

Project description:In most ecosystems, bacteria primarily exist as structured surface-associated biofilms that can be highly tolerant to antibiotics and thus represent an important health issue. Here we explored drug repurposing as a strategy to identify new antibiofilm compounds, screening over 1000 compounds from the Prestwick Chemical Library of approved drugs for specific activities that prevent biofilm formation by Escherichia coli. Most growth-inhibiting compounds, which include known antibacterial but also antiviral and other drugs, had also reduced biofilm formation. However, we also identified several drugs that were biofilm-inhibitory at doses where only weak or no effect on planktonic growth could be observed. Activities of the most specific antibiofilm compounds were further characterized using gene expression analysis, proteomics and microscopy. We observed that most of these drugs acted by repressing genes responsible for production of curli, major component of E. coli biofilm matrix. This repression apparently occurred through induction of several different stress responses, including DNA and cell-wall damage, and homeostasis of divalent cations, demonstrating that biofilm formation can be inhibited through a variety of molecular mechanisms. One tested drug, tyloxapol, inhibited biofilm formation independent of curli expression or growth, by suppressing bacterial attachment at the surface.

Project description:Wzx/Wzy- and ABC transporter-dependent pathways, an outer membrane (OM) polysaccharide export (OPX) type translocon exports the polysaccharide across the OM. The paradigm OPX protein WzaE. coli is an octamer, in which the eight C-terminal domains form an α-helical OM pore, and the eight copies of the three N-terminal domains (D1-D3) a periplasmic cavity. In synthase-dependent pathways, the OM translocon is a 16- to 18-stranded β-barrel protein. In Myxococcus xanthus, the secreted polysaccharide EPS is synthesized in a Wzx/Wzy-dependent pathway. Here, using experiments and computational structural biology, we characterize EpsX as an OM 18-stranded β-barrel protein important for EPS synthesis and identify AlgE, a β-barrel translocon of a synthase-dependent pathway, as its closest structural homolog. We also find that EpsY, the OPX protein of the EPS pathway, only consists of the periplasmic D1 and D2 domains and lacks the domain for spanning the OM (henceforth D1D2OPX protein). In vivo, EpsX and EpsY mutually stabilize each other, supporting their direct interaction. Based on these observations, we propose a model whereby EpsY and EpsX make up a novel type of translocon for polysaccharide export across the OM. Specifically, in this composite translocon, EpsX functions as the OM-spanning translocon together with the periplasmic D1D2OPX protein EpsY. Based on computational genomics, similar composite systems are present widespread in Gram-negative bacteria. This model provides a framework for these proteins' future experimental characterization.

Project description:Wzx/Wzy- and ABC transporter-dependent pathways, an outer membrane (OM) polysaccharide export (OPX) type translocon exports the polysaccharide across the OM. The paradigm OPX protein WzaE. coli is an octamer, in which the eight C-terminal domains form an α-helical OM pore, and the eight copies of the three N-terminal domains (D1-D3) a periplasmic cavity. In synthase-dependent pathways, the OM translocon is a 16- to 18-stranded β-barrel protein. In Myxococcus xanthus, the secreted polysaccharide EPS is synthesized in a Wzx/Wzy-dependent pathway. Here, using experiments and computational structural biology, we characterize EpsX as an OM 18-stranded β-barrel protein important for EPS synthesis and identify AlgE, a β-barrel translocon of a synthase-dependent pathway, as its closest structural homolog. We also find that EpsY, the OPX protein of the EPS pathway, only consists of the periplasmic D1 and D2 domains and lacks the domain for spanning the OM (henceforth D1D2OPX protein). In vivo, EpsX and EpsY mutually stabilize each other, supporting their direct interaction. Based on these observations, we propose a model whereby EpsY and EpsX make up a novel type of translocon for polysaccharide export across the OM. Specifically, in this composite translocon, EpsX functions as the OM-spanning translocon together with the periplasmic D1D2OPX protein EpsY. Based on computational genomics, similar composite systems are present widespread in Gram-negative bacteria. This model provides a framework for these proteins' future experimental characterization.