Search results for "Synthetic biology"

showing 10 items of 73 documents

Boolean computation in plants using post-translational genetic control and a visual output signal

2018

[EN] Due to autotrophic growing capacity and extremely rich secondary metabolism, plants should be preferred targets of synthetic biology. However, developments in plants usually run below those in other taxonomic groups. In this work we engineered genetic circuits capable of logic YES, OR and AND Boolean computation in plant tissues with a visual output signal. The circuits, which are deployed by means of Agrobacterium tumefaciens, perform with the conditional activity of the MYB transcription factor Roseal from Antirrhinum majus inducing the accumulation of anthocyanins, plant endogenous pigments that are directly visible to the naked eye or accurately quantifiable by spectrophotometric a…

0106 biological sciences0301 basic medicineProteasesmedicine.medical_treatmentRecombinant Fusion ProteinsPotyvirusBiomedical EngineeringAgrobacterium01 natural sciencesBiochemistry Genetics and Molecular Biology (miscellaneous)Anthocyanins03 medical and health sciencesViral ProteinsAntirrhinum majusAnthocyanins Biological computingmedicineAntirrhinumMYBSecondary metabolismTranscription factorSynthetic biologyPlant ProteinsProteasebiologyfungiPotyvirusfood and beveragesGeneral MedicineAgrobacterium tumefaciensbiology.organism_classificationPlants Genetically ModifiedCell biologyGENETICA030104 developmental biologySpectrophotometryGenetic circuitsPotyvirus proteaseSynthetic BiologyProtein Processing Post-Translational010606 plant biology & botanyPeptide HydrolasesPlasmidsTranscription Factors
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CRISPR-mediated strand displacement logic circuits with toehold-free DNA

2021

DNA nanotechnology, and DNA computing in particular, has grown extensively over the past decade to end with a variety of functional stable structures and dynamic circuits. However, the use as designer elements of regular DNA pieces, perfectly complementary double strands, has remained elusive. Here, we report the exploitation of CRISPR-Cas systems to engineer logic circuits based on isothermal strand displacement that perform with toehold-free double-stranded DNA. We designed and implemented molecular converters for signal detection and amplification, showing good interoperability between enzymatic and nonenzymatic processes. Overall, these results contribute to enlarge the repertoire of su…

0106 biological sciencesLetterTranscription GeneticComputer scienceStreptococcus pyogenesRibonuclease HBiomedical EngineeringDNA Single-StrandedNanotechnology01 natural sciencesBiochemistry Genetics and Molecular Biology (miscellaneous)Displacement (vector)law.invention03 medical and health sciencesSynthetic biologychemistry.chemical_compoundComputers MolecularDNA computinglaw010608 biotechnologyCRISPR-Associated Protein 9Biological computingDNA nanotechnologyCRISPRNanotechnologyClustered Regularly Interspaced Short Palindromic RepeatsGene Regulatory NetworksDNA nanotechnologySynthetic biology030304 developmental biologyElectronic circuit0303 health sciencesGeneral MedicineRibonuclease PancreaticchemistryLogic gatebiological computingsynthetic biologyCRISPR-Cas SystemsEndopeptidase KGenetic EngineeringDNARNA Guide Kinetoplastida
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Engineering CRISPR guide RNA riboswitches for in vivo applications

2019

CRISPR-based genome editing provides a simple and scalable toolbox for a variety of therapeutic and biotechnology applications. Whilst the fundamental properties of CRISPR proved easily transferable from the native prokaryotic hosts to eukaryotic and multicellular organisms, the tight control of the CRISPR-editing activity remains a major challenge. Here we summarise recent developments of CRISPR and riboswitch technologies and recommend novel functionalised synthetic-gRNA (sgRNA) designs to achieve inducible and spatiotemporal regulation of CRISPR-based genetic editors in response to cellular or extracellular stimuli. We believe that future advances of these tools will have major implicati…

0106 biological sciencesRiboswitchComputer scienceGenetic enhancementBiomedical EngineeringBioengineeringComputational biology01 natural sciences03 medical and health sciencesSynthetic biologyGenome editing010608 biotechnologyHumansCRISPRClustered Regularly Interspaced Short Palindromic RepeatsGuide RNAQH426030304 developmental biologyGene Editing0303 health sciencesReproducibility of ResultsRNAMulticellular organismRiboswitchGenetic EngineeringRNA Guide KinetoplastidaBiotechnologyCurrent Opinion in Biotechnology
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Artificial Biosystems by Printing Biology

2020

The continuous progress of printing technologies over the past 20 years has fueled the development of a plethora of applications in materials sciences, flexible electronics, and biotechnologies. More recently, printing methodologies have started up to explore the world of Artificial Biology, offering new paradigms in the direct assembly of Artificial Biosystems (small condensates, compartments, networks, tissues, and organs) by mimicking the result of the evolution of living systems and also by redesigning natural biological systems, taking inspiration from them. This recent progress is reported in terms of a new field here defined as Printing Biology, resulting from the intersection betwee…

02 engineering and technologyGeneral ChemistryTop-down and bottom-up design010402 general chemistry021001 nanoscience & nanotechnology01 natural sciences0104 chemical sciencesLiving systemsBiomaterialsSynthetic biologyBiomimetic MaterialsPrinting Three-DimensionalSystems engineeringaqueous compartments artificial biosystems life-like systems molecular printing synthetic biologyGeneral Materials ScienceSynthetic Biology0210 nano-technologyBiotechnology
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The Hidden Charm of Life

2019

Synthetic biology is an engineering view on biotechnology, which has revolutionized genetic engineering. The field has seen a constant development of metaphors that tend to highlight the similarities of cells with machines. I argue here that living organisms, particularly bacterial cells, are not machine-like, engineerable entities, but, instead, factory-like complex systems shaped by evolution. A change of the comparative paradigm in synthetic biology from machines to factories, from hardware to software, and from informatics to economy is discussed.

0301 basic medicineCharm (programming language)Computer scienceengineeringComplex system050905 science studiesliving systemGeneral Biochemistry Genetics and Molecular BiologyField (computer science)03 medical and health sciencesSynthetic biologyLiving systemEngineeringlcsh:ScienceEcology Evolution Behavior and SystematicsSynthetic biology05 social sciencesPaleontologyData science030104 developmental biologySpace and Planetary ScienceInformaticsPerspectivelcsh:Qsynthetic biology0509 other social sciencesBiotechnologybiotechnologyLife
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Strategies for structuring interdisciplinary education in Systems Biology: an European perspective

2016

Systems Biology is an approach to biology and medicine that has the potential to lead to a better understanding of how biological properties emerge from the interaction of genes, proteins, molecules, cells and organisms. The approach aims at elucidating how these interactions govern biological function by employing experimental data, mathematical models and computational simulations. As Systems Biology is inherently multidisciplinary, education within this field meets numerous hurdles including departmental barriers, availability of all required expertise locally, appropriate teaching material and example curricula. As university education at the Bachelor’s level is traditionally built upon…

0301 basic medicineEngineeringSystems biologymedia_common.quotation_subjectStructuringGeneral Biochemistry Genetics and Molecular BiologyArticleEducation03 medical and health sciences0302 clinical medicineExcellenceMultidisciplinary approachDrug DiscoveryComputingMilieux_COMPUTERSANDEDUCATIONLife ScienceSystems and Synthetic BiologyInnovation/dk/atira/pure/sustainabledevelopmentgoals/industry_innovation_and_infrastructureCurriculummedia_commonVLAGFlexibility (engineering)Systeem en Synthetische BiologieScience & TechnologyManagement sciencebusiness.industry4. EducationApplied MathematicsINF/01 - INFORMATICAGAPGénéralitésSystems Biology Training and education3. Good healthComputer Science Applications030104 developmental biologyAction (philosophy)Modeling and Simulationand InfrastructureSDG 9 - Industry Innovation and InfrastructureMathematical & Computational BiologySystems biologybusinessDisciplineSDG 9 - IndustryLife Sciences & Biomedicine030217 neurology & neurosurgery
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Probing the operability regime of an engineered ribocomputing unit in terms of dynamic range maintenance with extracellular changes and time

2020

Synthetic biology aims at engineering gene regulatory circuits to end with cells (re)programmed on purpose to implement novel functions or discover natural behaviors. However, one overlooked question is whether the resulting circuits perform as intended in variety of environments or with time. Here, we considered a recently engineered genetic system that allows programming the cell to work as a minimal computer (arithmetic logic unit) in order to analyze its operability regime. This system involves transcriptional and post-transcriptional regulations. In particular, we studied the analog behavior of the system, the effect of physicochemical changes in the environment, the impact on cell gro…

0301 basic medicineEnvironmental EngineeringOperabilityProcess (engineering)Computer scienceSystems biologyBiomedical EngineeringHeterologous03 medical and health sciencesArithmetic logic unitSynthetic biology0302 clinical medicinelcsh:QH301-705.5Molecular BiologySynthetic biologyBiological computationResearchCell BiologyExpression (computer science)030104 developmental biologyRegulatory RNAlcsh:Biology (General)Heterologous expressionBiological systemSystems biology030217 neurology & neurosurgery
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Model-based design of RNA hybridization networks implemented in living cells

2017

[EN] Synthetic gene circuits allow the behavior of living cells to be reprogrammed, and non-coding small RNAs (sRNAs) are increasingly being used as programmable regulators of gene expression. However, sRNAs (natural or synthetic) are generally used to regulate single target genes, while complex dynamic behaviors would require networks of sRNAs regulating each other. Here, we report a strategy for implementing such networks that exploits hybridization reactions carried out exclusively by multifaceted sRNAs that are both targets of and triggers for other sRNAs. These networks are ultimately coupled to the control of gene expression. We relied on a thermo-dynamic model of the different stable…

0301 basic medicineGeneticsNetwork architectureModels GeneticQHGene regulatory networkRNAGene ExpressionNucleic Acid HybridizationBiology03 medical and health sciencesNucleic acid thermodynamics030104 developmental biologyGene expressionModel-based designGeneticsEscherichia coliRNAThermodynamicsGene Regulatory NetworksSingle-Cell AnalysisSynthetic Biology and BioengineeringGeneQH426Function (biology)
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High-Performance Biocomputing in Synthetic Biology-Integrated Transcriptional and Metabolic Circuits

2019

Biocomputing uses molecular biology parts as the hardware to implement computational devices. By following pre-defined rules, often hard-coded into biological systems, these devices are able to process inputs and return outputs-thus computing information. Key to the success of any biocomputing endeavor is the availability of a wealth of molecular tools and biological motifs from which functional devices can be assembled. Synthetic biology is a fabulous playground for such purpose, offering numerous genetic parts that allow for the rational engineering of genetic circuits that mimic the behavior of electronic functions, such as logic gates. A grand challenge, as far as biocomputing is concer…

0301 basic medicineHistologyComputer scienceProcess (engineering)lcsh:BiotechnologyBiomedical EngineeringBioengineering02 engineering and technologyField (computer science)Metabolic engineering03 medical and health sciencesSynthetic biologygenetic circuitslcsh:TP248.13-248.65ConceptualizationIntersection (set theory)business.industryBioengineering and Biotechnologybiocomputing021001 nanoscience & nanotechnologyboolean logic030104 developmental biologyPerspectiveKey (cryptography)metabolic networkssynthetic biology0210 nano-technologySoftware engineeringbusinessmetabolic engineeringHost (network)Biotechnology
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Crossing kingdoms:How can art open up new ways of thinking about science?

2020

“Crossing Kingdoms” is an artist-led experiment in the biological fusion of mammalian and yeast cells and the cultural discussions of these phenomena. We present this collaboration as an experiment in responsible research and innovation (RRI), an institutionalized format for ensuring that researchers reflect on the wider social dimensions of their work. Our methods challenged us as researchers to reflect on interdisciplinary collaboration and the possibility of innovating in biology for artistic purposes, challenged audiences to reflect on biological boundaries, and challenged both groups to reflect on what it means to be responsible in science. We conclude that our experiment in RRI was su…

0301 basic medicineHistologylcsh:BiotechnologyBiomedical Engineeringresponsible research and innovationhybrid taxaBioengineering02 engineering and technologySocial dimension03 medical and health sciencesSynthetic biologyKingdominterdisciplinaritylcsh:TP248.13-248.65responsible research and innovation (RRI)Responsible Research and InnovationBioengineering and Biotechnologyart-science collaboration021001 nanoscience & nanotechnology030104 developmental biologyPerspectiveStandard protocolEngineering ethicssynthetic biology0210 nano-technologyBiotechnology
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