Project description:There is great need for therapeutics against multi-drug resistant, Gram-negative bacterial pathogens. Recently, darobactin A, a novel bicyclic heptapeptide that selectively kills Gram-negative bacteria by targeting the outer-membrane protein BamA, was discovered. Its efficacy was proven in animal infection models of Escherichia coli, Klebsiella pneumoniae and Pseudomonas aeruginosa, thus promoting darobactin A as a promising lead compound. Originally discovered from members of the nematode symbiotic genus Photorhabdus, the biosynthetic gene cluster (BGC) encoding for the synthesis of darobactin A can also be found in other γ-proteobacterial families. Therein, the precursor peptides DarB-F, which differ in their core sequence from darobactin A, were identified in silico. Even though production of these analogs was not observed in the putative producer strains, we were able to generate them by mutasynthetic derivatization of a heterologous expression system. The generated analogs were isolated and tested for their bioactivity. The most potent compound, darobactin B, was used for co-crystallization with the target BamA, revealing an identical binding site to darobactin A. Besides its potency, darobactin B did not exhibit cytotoxicity and was slightly more active against Acinetobacter baumanii isolates than darobactin A. Furthermore, we evaluated the plasma protein binding of darobactin A and B, indicating their different pharmacokinetic properties. This is the first report on new members of this new antibiotics class, which is likely to expand to several promising therapeutic candidates.

Project description:Acinetobacter baumannii is a nosocomial Gram-negative pathogen that often displays multidrug-resistance due to its robust outer membrane and its ability to acquire and retain extracellular DNA. Moreover, it can survive for prolonged durations on surfaces and is resistant to desiccation. Discovering new antibiotics against A. baumannii has proven challenging through conventional screening approaches. Fortunately, machine learning methods allow for the rapid exploration of chemical space, increasing the probability of discovering new chemical matter with antibacterial activity against this burdensome pathogen. Here, we screened ~7,500 molecules for those that inhibited the growth of A. baumannii in vitro. We trained a deep neural network with this growth inhibition dataset and performed predictions on the Drug Repurposing Hub for structurally novel molecules with activity against A. baumannii. Through this approach, we discovered abaucin, an antibacterial compound with narrow-spectrum activity against A. baumannii, which could overcome intrinsic and acquired resistance mechanisms in clinical isolates. Further investigations revealed that abaucin perturbs lipoprotein trafficking through a mechanism involving LolE, a functionally conserved protein that contributes to shuttling lipoproteins from the inner membrane to the outer membrane. Moreover, abaucin was able to control an A. baumannii infection in a murine wound model. Together, this work highlights the utility of machine learning in discovering new antibiotics and describes a promising lead with narrow-spectrum activity against a challenging Gram-negative pathogen.

Project description:Guanidine DNA quadruplex (G4-DNA) structures convey a distinctive layer of epigenetic information that is critical for the regulation of key biological activities and processes as genome transcription regulation, replication and repair. Despite several works that have been published recently, the information regarding their role and possible use as therapeutic drug targets in bacteria is still scarce. Here, we tested the biological activity of a small G4-DNA ligand library based on the naphthalene diimide (NDI) pharmacophore, against both Gram-positive and Gram-negative bacteria. For the best compound identified, NDI-10, the action mechanism was further characterized. Gram-negative bacteria were more resistant altogether due to the presence of the outer membrane, although the activity of the G4-Ligand was generally bactericidal, while it was bacteriostatic for Gram-positive bacteria. This asymmetric activity could be related to the different prevalence of putative G4-DNA structures in each group, the influence that they can exert on the gene expression (which was found more severe for the Gram-negative bacteria) and the role of the G4 structures in these bacteria, that seems to be more related to promote transcription in Gram-positive bacteria and repress transcription in Gram-negative.

Project description:The alarming increase in antimicrobial resistance (AMR) will soon limit treatment options for even routine infections, especially those caused by Gram-negative bacteria such as Acinetobacter baumannii. Here, we report a two-pronged approach to identify new vulnerabilities in such pathogens. Staring from diphenyleneiodonium (dPI) salts, which are compounds that have moderate antimicrobial activity against Gram-positive pathogens, we synthesized a focused heterocyclic library and report a new analogue that has much higher inhibitory potency against multidrug-resistant Acinetobacter baumannii and excellent efficacy in reduction of bacterial burden in a mouse neutropenic thigh infection model. The lead compound was also found to synergize with aminoglycosides, which are routinely used in the treatment of such infections in humans. Further, we synthesized an alkyne containing probe and using gel and mass spectrometry base chemoproteomics platforms, we identified proteins that have redox cofactors as putative targets for this class of compounds. Additionally, we also demonstrate that the modification of proteins is covalent and through a cysteine residue. Together, using complementary chemical biology approaches, new vulnerabilities in Gram-negative pathogens were identified that would help address a burgeoning global problem of AMR.

Project description:The current study re-defines a method to reveal bioactive compounds from the crude extracts of Malaysian red seaweed Gracilaria edulis, having promising antibacterial activities against selected bacterial species. Three species of Gram-positive and - negative characters were remarkably inhibited by the sequential and direct extracts of ethyl acetate and acetone. These were further separated through chromatographic methods to reveal a plethora of chemical constituents to be considered for a downstream virtual screening against selected crucial proteins of the six bacteria.

Project description:Screening large molecule libraries against pathogenic bacteria is often challenged by a low hit rate due to limited uptake, underrepresentation of antibiotic structural motifs and assays which do not resemble the infection conditions. To address these limitations, we here screen a library focused on alkylguanidinium compounds, a structural motif associated with antibiotic activity and enhanced uptake, under host-mimicking infection conditions against a panel of disease-associated bacteria. Several hit molecules were obtained with activities against Gram-positive as well as Gram-negative bacteria highlighting the fidelity of the general concept. Based on the best antibiotic activity, we selected one compound (L15) for in-depth mode of action studies. L15 exhibited bactericidal activity against Staphylococcus aureus USA300 Lac (JE2) with a minimum inhibitory concentration of 1.5 µM whereby a structure-activity relationship study with 18 derivatives proved the necessity of the guanidinium motif for antibiotic activity. Electron microscopy studies and depolarization assays at high L15 concentrations showed an impact on the cell membrane and integrity which was absent at the MIC concentration. Sequencing of L15-resistant strains revealed a mutation in an efflux pump but did not provide hints for direct targets. We thus performed affinity-based protein profiling with a L15 probe and identified signal peptidase IB (SpsB) as the most promising hit. Validation by activity assays, binding site identification and molecular docking demonstrated SpsB overactivation by L15, similar to a previously reported activator molecule that dysregulates protein secretion of this essential enzyme. Overall, this study highlights the need for unconventional screening strategies to identify novel antibiotics.

Project description:Screening of various bisquaternary bisnaphthalimides against a variety of human pathogens revealed one compound, designated MT02, with strong inhibitory effects against gram-positive bacteria. The minimal inhibitory concentrations ranged from 0.31 µg/ml against community-acquired methicillin resistant Staphylococcus aureus (MRSA) strain USA300 to 20 µg/ml against Streptococcus pneumonia. DNA-microarray studies generated a transcriptional signature characterized by a strong increase of genes involved in DNA-metabolism, DNA-replication, SOS-response and transport of positively charged compounds. Radioactive whole cell labeling experiments indicated a strong impact of MT02 on bacterial DNA-replication. Furthermore, surface plasmon resonance and gel retardation experiments demonstrated direct binding of MT02 to DNA in a concentration dependent, reversible and sequence-unspecific manner. The data presented suggest that the bisquaternary bisnaphthalimide MT02 exerts anti-gram-positive activity by binding to DNA and thereby prohibiting appropriate DNA-replication. WT strain exposed to MT02 for 60 minutes in rich medium

Project description:Screening of various bisquaternary bisnaphthalimides against a variety of human pathogens revealed one compound, designated MT02, with strong inhibitory effects against gram-positive bacteria. The minimal inhibitory concentrations ranged from 0.31 µg/ml against community-acquired methicillin resistant Staphylococcus aureus (MRSA) strain USA300 to 20 µg/ml against Streptococcus pneumonia. DNA-microarray studies generated a transcriptional signature characterized by a strong increase of genes involved in DNA-metabolism, DNA-replication, SOS-response and transport of positively charged compounds. Radioactive whole cell labeling experiments indicated a strong impact of MT02 on bacterial DNA-replication. Furthermore, surface plasmon resonance and gel retardation experiments demonstrated direct binding of MT02 to DNA in a concentration dependent, reversible and sequence-unspecific manner. The data presented suggest that the bisquaternary bisnaphthalimide MT02 exerts anti-gram-positive activity by binding to DNA and thereby prohibiting appropriate DNA-replication.

Project description:Isonitrile natural products exhibit promising antibacterial activities, however, their mode of action (MoA) remains largely unknown. Based on the nanomolar potency of xanthocillin X (Xan) against diverse difficult-to-treat Gram-negative bacteria, including the critical priority pathogen Acinetobacter baumannii, we performed in-depth studies to decipher its MoA. While neither metal binding nor cellular protein targets were relevant for Xan´s antibiotic effects, sequencing of resistant strains revealed a conserved mutation in the heme biosynthesis enzyme porphobilinogen synthase (PbgS). This mutation caused impaired enzymatic efficiency indicative of reduced heme production. This discovery led to the validation of an untapped mechanism by which direct heme sequestration of Xan prevents its binding into cognate enzyme pockets resulting in uncontrolled cofactor biosynthesis, accumulation of porphyrins and corresponding stress with deleterious effects for bacterial viability. Thus, Xan represents a promising antibiotic displaying activity even against multidrug resistant strains while exhibiting low toxicity to human cells.

Project description:Gram-negative bacterial infections are causing increasing levels of morbidity due to the rise of resistance to established antibiotics. New antibiotic classes with distinct molecular mode of action are therefore required. Recently, a family of macrocyclic peptidomimetics was discovered that target the outer membrane LPS transport protein LptD to specifically inhibit bacterial growth in Pseudomonas spp. To characterize the interaction of these antibiotics with LptD from P. aeruginosa, we combined photo-crosslinkable peptidomimetics and hypothesis-free mass spectrometry-based proteomics. We provide evidence that the antibiotic cross-links to the periplasmic segment of LptD, containing a ß-jellyroll domain and an N-terminal insert domain that is characteristic of Pseudomonas spp. Binding of the antibiotic to the periplasmic segment of LptD is expected to block LPS transport, consistent with the proposed mode of action and observed specificity of these antibiotics. These insights may prove valuable for the discovery of new antibiotics targeting the LPS transport pathway in other Gram-negative bacteria.