Your search keyword '"Menolascina F"' showing total 3 results

1. A bacterial pathogen uses dimethylsulfoniopropionate as a cue to target heat-stressed corals

Author

Garren, M, Son, K, Raina, JB, Rusconi, R, Menolascina, F, Shapiro, OH, Tout, J, Bourne, DG, Seymour, JR, and Stocker, R

Subjects

Hot Temperature, Coral Reefs, Chemotaxis, fungi, technology, industry, and agriculture, Sulfonium Compounds, biochemical phenomena, metabolism, and nutrition, Anthozoa, Microbiology, Animals, Seawater, geographic locations, Sulfur, Vibrio

Abstract

Diseases are an emerging threat to ocean ecosystems. Coral reefs, in particular, are experiencing a worldwide decline because of disease and bleaching, which have been exacerbated by rising seawater temperatures. Yet, the ecological mechanisms behind most coral diseases remain unidentified. Here, we demonstrate that a coral pathogen, Vibrio coralliilyticus, uses chemotaxis and chemokinesis to target the mucus of its coral host, Pocillopora damicornis. A primary driver of this response is the host metabolite dimethylsulfoniopropionate (DMSP), a key element in the global sulfur cycle and a potent foraging cue throughout the marine food web. Coral mucus is rich in DMSP, and we found that DMSP alone elicits chemotactic responses of comparable intensity to whole mucus. Furthermore, in heat-stressed coral fragments, DMSP concentrations increased fivefold and the pathogen's chemotactic response was correspondingly enhanced. Intriguingly, despite being a rich source of carbon and sulfur, DMSP is not metabolized by the pathogen, suggesting that it is used purely as an infochemical for host location. These results reveal a new role for DMSP in coral disease, demonstrate the importance of chemical signaling and swimming behavior in the recruitment of pathogens to corals and highlight the impact of increased seawater temperatures on disease pathways. © 2014 International Society for Microbial Ecology All rights reserved.

Published

2013

2. Engineering and control of biological systems: A new way to tackle complex diseases

Author

Diego di Bernardo, Filippo Menolascina, Velia Siciliano, Menolascina, F, Siciliano, V, and DI BERNARDO, Diego

Subjects

Systems biology, Biophysics, Functional genes, Biology, Bioinformatics, Biochemistry, Modelling, Synthetic biology, Network motif, Human health, Structural Biology, Genetics, Animals, Humans, Disease, Molecular Biology, Management science, Control engineering, Cell Biology, Multicellular organism, Synthetic Biology, ComputingMethodologies_GENERAL, Genetic Engineering, Merge (version control)

Abstract

The ongoing merge between engineering and biology has contributed to the emerging field of synthetic biology. The defining features of this new discipline are abstraction and standardisation of biological parts, decoupling between parts to prevent undesired cross-talking, and the application of quantitative modelling of synthetic genetic circuits in order to guide their design. Most of the efforts in the field of synthetic biology in the last decade have been devoted to the design and development of functional gene circuits in prokaryotes and unicellular eukaryotes. Researchers have used synthetic biology not only to engineer new functions in the cell, but also to build simpler models of endogenous gene regulatory networks to gain knowledge of the “rules” governing their wiring diagram. However, the need for innovative approaches to study and modify complex signalling and regulatory networks in mammalian cells and multicellular organisms has prompted advances of synthetic biology also in these species, thus contributing to develop innovative ways to tackle human diseases. In this work, we will review the latest progress in synthetic biology and the most significant developments achieved so far, both in unicellular and multicellular organisms, with emphasis on human health.

Published

2012

3. Construction and Modelling of an Inducible Positive Feedback Loop Stably Integrated in a Mammalian Cell-Line

Author

Diego di Bernardo, Maria Nicoletta Moretti, Velia Siciliano, Chiara Fracassi, Immacolata Garzilli, Lucia Marucci, Filippo Menolascina, Siciliano, V, Menolascina, F, Marucci, L, Fracassi, C, Garzilli, Immacolata, Moretti, Mn, and DI BERNARDO, Diego

Subjects

Yellow fluorescent protein, Transcription, Genetic, QH301-705.5, Systems biology, Bioengineering, CHO Cells, Cellular and Molecular Neuroscience, Transactivation, Engineering, Cricetulus, Transcription (biology), Cricetinae, Biological Systems Engineering, Genetics, Animals, Homeostasis, Humans, Control Theory, Biology (General), Biology, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Positive feedback, Feedback, Physiological, Regulation of gene expression, Models, Genetic, Ecology, biology, Reverse Transcriptase Polymerase Chain Reaction, Systems Biology, Applied Mathematics, HEK 293 cells, DNA, Molecular biology, Cell biology, HEK293 Cells, Nonlinear Dynamics, Gene Expression Regulation, Computational Theory and Mathematics, Doxycycline, Modeling and Simulation, biology.protein, Synthetic Biology, Signal transduction, Mathematics, Research Article

Abstract

Understanding the relationship between topology and dynamics of transcriptional regulatory networks in mammalian cells is essential to elucidate the biology of complex regulatory and signaling pathways. Here, we characterised, via a synthetic biology approach, a transcriptional positive feedback loop (PFL) by generating a clonal population of mammalian cells (CHO) carrying a stable integration of the construct. The PFL network consists of the Tetracycline-controlled transactivator (tTA), whose expression is regulated by a tTA responsive promoter (CMV-TET), thus giving rise to a positive feedback. The same CMV-TET promoter drives also the expression of a destabilised yellow fluorescent protein (d2EYFP), thus the dynamic behaviour can be followed by time-lapse microscopy. The PFL network was compared to an engineered version of the network lacking the positive feedback loop (NOPFL), by expressing the tTA mRNA from a constitutive promoter. Doxycycline was used to repress tTA activation (switch off), and the resulting changes in fluorescence intensity for both the PFL and NOPFL networks were followed for up to 43 h. We observed a striking difference in the dynamics of the PFL and NOPFL networks. Using non-linear dynamical models, able to recapitulate experimental observations, we demonstrated a link between network topology and network dynamics. Namely, transcriptional positive autoregulation can significantly slow down the “switch off” times, as comparared to the nonautoregulatated system. Doxycycline concentration can modulate the response times of the PFL, whereas the NOPFL always switches off with the same dynamics. Moreover, the PFL can exhibit bistability for a range of Doxycycline concentrations. Since the PFL motif is often found in naturally occurring transcriptional and signaling pathways, we believe our work can be instrumental to characterise their behaviour., Author Summary Synthetic Biology aims at designing and building new biological functions in living organisms. At the same time, Synthetic Biology approaches can be used to uncover the design principles of natural biological systems through the rational construction of simplified regulatory networks. Mathematical models of the networks are then derived from physical considerations and can be used to explain the observed dynamical behaviours. We have characterised a regulatory motif often found in transcriptional and signalling pathways. We constructed a positive feedback loop motif in mammalian cells, consisting of a protein controlling its own expression. We have shown that this motif exhibits a dynamic behaviour which is very different from that obtained when the autoregulation is removed. This difference is intrinsic to the specific wiring diagram chosen by the cell to control its behaviour (feedback versus non-feedback configurations), and can be instrumental in understanding the complex network of regulation occurring in a cell.

Published

2011