Details about this organism
Synonyms (2)Filterable agent of primary atypical pneumonia, Schizoplasma pneumoniae
Definitions (0)
None defined
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Strain details
Name | Provider name | Provider's strain ID | Genotypes | Phenotypes | Synonym | Comments | Based on |
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Related items
Projects that do not fall under current programmes.
Projects: Manchester Institute for Biotechnology, ICYSB 2015 - International Practical Course in Systems Biology, iRhythmics, INBioPharm, EmPowerPutida, Systo models, MycoSynVac - Engineering Mycoplasma pneumoniae as a broad-spectrum animal vaccine, Multiscale modelling of state transitions in the host-microbiome-brain network, Extremophiles metabolsim, NAD COMPARTMENTATION, Agro-ecological modelling, Bergen(Ziegler lab) project AF-NADase, NAMPT affinity, Stress granules, Modelling COVID-19 epidemics, Bio-crop, ORHIZON, Coastal Data, SASKit: Senescence-Associated Systems diagnostics Kit for cancer and stroke, hybrid sequencing, HOST-PAR, BioCreative VII, Boolean modeling of Parkinson disease map, Orphan cytochrome P450 20a1 CRISPR/Cas9 mutants and neurobehavioral phenotypes in zebrafish, Selective Destruction in Ageing, Viral Metagenomic, Synthetic biology in Synechococcus for bioeconomy applications (SynEco), testproject, SDBV ephemeral data exchanges, Test project, The BeeProject, PHENET, LiceVault, EbN1 Systems Biology
Web page: Not specified
The MycoSynVac project AIMS at using cutting-edge synthetic biology methodologies to engineer Mycoplasma pneumoniae as a universal chassis for vaccination. Designing a universal Mycoplasma chassis that can be deployed as single- or multi-vaccine in a range of animal hosts. Annually, infections caused by Mycoplasma species in poultry, cows, and pigs result in multimillion Euro losses in the USA and Europe. There is no effective vaccination against many Mycoplasmas that infect pets, humans and farm ...
Programme: Independent Projects
Public web page: http://www.mycosynvac.eu/
Organisms: Mycoplasma pneumoniae
Dynamic model of glycolysis, pyruvate metabolism and NoxE. The model is parameterized by selecting the best out of 100 parameter set using Copasi's Genetic algorithm with 1000 itterations and 500 simmulatanious models.
Creator: Niels Zondervan
Submitter: Niels Zondervan
Model type: Ordinary differential equations (ODE)
Model format: SBML
Environment: Not specified
Organism: Mycoplasma pneumoniae
Investigations: Modelling of M. pneumoniae metabolism
Studies: Core Model predictions, Core Model training, Core model predicting combined mutations and pe...
Assays: 40 samples, OE mutants of glycolysis and pyruva..., Construction and training of the core model, Dynamic model simmulation pipeline, Metabolic control analysis (local and global), Validation by simulating independent mutant and...
Core model with the addition of a NoxE reaction to regenerate NAD using O2. COPASI’s build in Evolutionary programming algorithm was used to estimate parameters using a maximum of 2000 generations with a population size of 100 models with value scaling as weights to train the 5 parameters of the NoxE reaction.
Creator: Niels Zondervan
Submitter: Niels Zondervan
Model type: Not specified
Model format: Copasi
Environment: Copasi
Organism: Mycoplasma pneumoniae
Investigations: Modelling of M. pneumoniae metabolism
Studies: Core Model training