Targeting Bacterial Central Metabolism for Drug Development

Current antibiotics, derived mainly from natural sources, inhibit a narrow spectrum of cellular processes, namely DNA replication, protein synthesis, and cell wall biosynthesis. With the worldwide explosion of drug resistance, there is renewed interest in the investigation of alternate essential cellular processes, including bacterial central metabolic pathways, as a drug target space for the next generation of antibiotics. However, the validation of targets in central metabolism is more complex, as essentiality of such targets can be conditional and/or contextual. Bearing in mind our enhanced understanding of prokaryotic central metabolism, a key question arises: can central metabolism be bacteria's Achilles' heel and a therapeutic target for the development of new classes of antibiotics? In this review, we draw lessons from oncology and attempt to address some of the open questions related to feasibility of targeting bacterial central metabolism as a strategy for developing new antibacterial drugs.

A Novel 3D hydrogel based microfluidic cell culture platform

Keshav Krishnamani

Breakthroughs in health care over the coming decades may well consist of cell based therapeutics, potentially allowing the repair and replacement of damaged tissues and organs. Recently developed induced pluripotency methods as well as advances in stem cell biology show hope of such a reality. But such prospects come with the need to have a robust understanding and control over cell development and differentiation processes. Cells in the body develop in tightly controlled and specialized micro-environments that provide many complex cues and interactions that guide cell fate by directing gene expression. But current cell culture techniques that are most widely used to study the cell outside the body have not significantly changed from when first started over a century ago, using simple containers and flasks with plastic surfaces. Many studies have shown that three-dimensions (3D) over conventional 2D cell culture alone, showed to have increased levels of cell organization, morphology and function. By combining novel biomaterials and microfabrication methods, this project aims to create a tool that allows the study of cells within a simplified 3D environment. With the potential to build up the physical and soluble complexity of this environment in a tailor made fashion, a "dissection" of the functions and influences of external factors may be understood. Such a tool can also be used for the development of cell based models, highly relevant for drug discovery application as well as potentially for the development of cell based therapeutics. We have developed a novel microfluidic 3D cell culture platform that allows controlled soluble factor perfusion in an enzymatically formed and cell responsive PEG-based hydrogel. Soft lithographic processes were used to mold microchannels on a layer of hydrogel. In a second step, a flat hydrogel layer is placed on top to enclose and form the microchannels . The system allows the control over soluble factor delivery and it is able to perform long-term cell culture and generate user controlled gradients of soluble factors. With continuous perfusion, metabolic waste is constantly removed and cells are supplied with fresh medium. The platform also can allow creation of tailor made environments building up complexity in a controlled fashion. Higher throughput is also achieved by arraying individual culture chambers. The device was applied towards the culture of mouse embryonic stem cells (mESC) in order to demonstrate their self-renewal capacity on the microfluidic platform. The effects of some cytokine factors were also studied. Meaningful readouts such as fluorescence are easily used for analysis and cells can possibly be extracted from the device for further downstream analysis and processing. Through this device we show that microfluidics technologies combined with biomaterials enables the creation of platforms that are biologically relevant for the study and understanding of cell processes from cancer to stem cell development, processes which are fundamentally regulated by interactions with the microenvironment. The platform developed may also be used to develop human tissue models perhaps more relevant than current animal based testing, providing new tools for drug development and also potentially new approaches for developing cell based therapeutics

2009

Deguelin exerts potent nematocidal activity via the mitochondrial respiratory chain

Johan Auwerx, Matteo Cornaglia, Martinus Gijs, Abdul Jabbar, Laurent Mouchiroud

As a result of limited classes of anthelmintics and an over-reliance on chemical control, there is a great need to discover new compounds to combat drug resistance in parasitic nematodes. Here, we show that deguelin, a plant-derived rotenoid, selectively and potently inhibits the motility and development of nematodes, which supports its potential as a lead candidate for drug development. Furthermore, we demonstrate that deguelin treatment significantly increases gene transcription that is associated with energy metabolism, particularly oxidative phosphorylation and mitoribosomal protein production before inhibiting motility. Mitochondrial tracking confirmed enhanced oxidative phosphorylation. In accordance, real-time measurements of oxidative phosphorylation in response to deguelin treatment demonstrated an immediate decrease in oxygen consumption in both parasitic (Haemonchus contortus) and free-living (Caenorhabditis elegans) nematodes. Consequently, we hypothesize that deguelin is exerting its toxic effect on nematodes as a modulator of oxidative phosphorylation. This study highlights the dynamic biologic response of multicellular organisms to deguelin perturbation.-Preston, S., Korhonen, P. K., Mouchiroud, L., Cornaglia, M., McGee, S. L., Young, N. D., Davis, R. A., Crawford, S., Nowell, C., Ansell, B. R. E., Fisher, G. M., Andrews, K. T., Chang, B. C. H., Gijs, M. A. M., Sternberg, P. W., Auwerx, J., Baell, J., Hofmann, A., Jabbar, A., Gasser, R. B. Deguelin exerts potent nematocidal activity via the mitochondrial respiratory chain.

Federation Amer Soc Exp Biol2017

Mycobacterium tuberculosis persistence mutants identified by screening in isoniazid-treated mice

Neeraj Dhar, John McKinney

Tuberculosis (TB) is notoriously difficult to cure, requiring administration of multiple antibiotics for 6 mo or longer. Conventional anti-TB drugs inhibit biosynthetic processes involved in cell growth and division, such as DNA replication, RNA transcription, protein translation, and cell wall biogenesis. Although highly effective against bacteria cultured in vitro under optimal growth conditions, these antibiotics are less effective against bacteria grown in vivo in the tissues of a mammalian host. The factors that contribute to the antibiotic tolerance of bacteria grown in vivo are unknown, although altered metabolism and sluggish growth are hypothesized to play a role. To address this question, we identified mutations in Mycobacterium tuberculosis that impaired or enhanced persistence in mice treated with isoniazid (INH), a front-line anti-TB drug. Disruption of cydC, encoding a putative ATP-binding cassette transporter subunit, accelerated bacterial clearance in INH-treated mice without affecting growth or survival in untreated mice. Conversely, transposon insertions within the rv0096-rv0101 gene cluster attenuated bacterial growth and survival in untreated mice but paradoxically prevented INH-mediated killing of bacteria in treated mice. These contrasting phenotypes were dependent on the interaction of the bacteria with the tissue environment because both mutants responded normally to INH when grown in macrophages ex vivo or in axenic cultures in vitro. Our findings have important implications because persistence-impairing mutations would be missed by conventional genetic screens to identify candidate drug targets. Conversely, persistence-enhancing mutations would be missed by standard diagnostic methods, which are performed on bacteria grown in vitro, to detect drug resistance.

2010

A Novel 3D hydrogel based microfluidic cell culture platform

Keshav Krishnamani

2009