Reaction Inclusion by Parsimony and Transcript Distribution (RIPTiDe)
Project description
RIPTiDe
Reaction Inclusion by Parsimony and Transcript Distribution
Transcriptomic analyses of bacteria have become instrumental to our understanding of their responses to changes in their environment. While traditional analyses have been informative, leveraging these datasets within genome-scale metabolic network reconstructions can provide greatly improved context for shifts in pathway utilization and downstream/upstream ramifications for changes in metabolic regulation. Previous techniques for transcript integration have focused on creating maximum consensus with the input datasets. However, these approaches have collectively performed poorly for metabolic predictions even compared to transcript-agnostic approaches of flux minimization that identifies the most efficient patterns of metabolism given certain growth constraints. Our new method, RIPTiDe, combines these concepts and utilizes overall minimization of flux in conjunction with transcriptomic analysis to identify the most energy efficient pathways to achieve growth that include more highly transcribed enzymes. RIPTiDe requires a low level of manual intervention which leads to reduced bias in predictions.
Please cite when using:
Jenior ML, Moutinho TJ, and Papin JA. (2019). Parsimonious transcript data integration improves context-specific predictions of bacterial metabolism in complex environments. bioRxiv 637124; doi: https://doi.org/10.1101/637124
Utilizes python implementation of the gapsplit flux sampler. Please also cite:
Keaty TC and Jensen PA (2019). gapsplit: Efficient random sampling for non-convex constraint-based models. bioRxiv 652917; doi: https://doi.org/10.1101/652917
Dependencies
>=python-3.6.4
>=cobra-0.15.3
>=pandas-0.24.1
>=symengine-0.4.0
>=scipy-1.3.0
Installation
Installation is:
$ pip install riptide
Or from github:
$ pip install git+https://github.com/mjenior/riptide
Usage
from riptide import *
my_model = cobra.io.read_sbml_model('examples/genre.sbml')
transcript_abundances_1 = riptide.read_transcription_file(read_abundances_file='examples/transcriptome1.tsv')
transcript_abundances_2 = riptide.read_transcription_file(read_abundances_file='examples/transcriptome2.tsv')
transcript_abundances_1 = riptide.read_transcription_file('examples/transcriptome1.tsv')
transcript_abundances_2 = riptide.read_transcription_file('examples/transcriptome2.tsv', replicates=True)
riptide_object_1_a = riptide.contextualize(model=my_model, transcriptome=transcript_abundances_1)
riptide_object_1_b = riptide.contextualize(model=my_model, transcriptome=transcript_abundances_1, include=['rxn1'], exclude=['rxn2','rxn3'])
riptide_object_2 = riptide.contextualize(model=my_model, transcriptome=transcript_abundances_2)
Additional parameters for main RIPTiDe functions:
riptide.read_transcription_file()
read_abundances_file : string
User-provided file name which contains gene IDs and associated transcription values
header : boolean
Defines if read abundance file has a header that needs to be ignored
default is no header
replicates : boolean
Defines if read abundances contains replicates and medians require calculation
default is no replicates (False)
sep: string
Defines what character separates entries on each line
defaults to tab (.tsv)
riptide.contextualize()
model : cobra.Model
The model to be contextualized (REQUIRED)
transcriptome : dictionary
Dictionary of transcript abundances, output of read_transcription_file (REQUIRED)
samples : int
Number of flux samples to collect, default is 500
norm : bool
Normalize transcript abundances using RPM calculation
Performed by default
fraction : float
Minimum percent of optimal objective value during FBA steps
Default is 0.8
minimum : float
Minimum linear coefficient allowed during weight calculation for pFBA
Default is None
conservative : bool
Conservatively remove inactive reactions based on genes
Default is False
bound : bool
Bounds each reaction based on transcriptomic constraints
Default is False
objective : bool
Sets previous objective function as a constraint with minimum flux equal to user input fraction
Default is True
set_bounds : bool
Uses flax variability analysis results from constrained model to set new bounds for all equations
Default is True
include : list
List of reaction ID strings for forced inclusion in final model
exclude : list
List of reaction ID strings for forced exclusion from final model
Example stdout report:
Initializing model and integrating transcriptomic data...
Pruning zero flux subnetworks...
Analyzing context-specific flux distributions...
Reactions pruned to 285 from 1129 (74.76% change)
Metabolites pruned to 285 from 1132 (74.82% change)
Flux through the objective DECREASED to ~54.71 from ~65.43 (16.38% change)
Contextualized metabolism has a concordance score of 45.4% (p=0.015)
RIPTiDe completed in 31 seconds
Resulting RIPTiDe object (class) properties:
- model - Contextualized genome-scale metabolic network reconstruction
- transcriptome - Dictionary of transcriptomic abundances provided by user
- coefficients - Dictionary of linear coefficients assigned to each reaction based on transcript values
- flux_samples - Flux sampling pandas object from constrained model
- flux_variability - Flux variability analysis pandas object from constrained model
- fraction_of_optimum - Minimum specified percentage of optimal objective flux during contextualization
- user_defined - User defined reactions in a 2 element dictionary that either were included or excluded
- concordance - Dictionary of linear coefficients and median fluxes from sampling, as well as Spearman correlation results
Additional Information
Thank you for your interest in RIPTiDe, for additional questions please email mljenior@virginia.edu.
If you encounter any problems, please file an issue along with a detailed description.
Distributed under the terms of the MIT license, "riptide" is free and open source software
Project details
Release history Release notifications | RSS feed
Download files
Download the file for your platform. If you're not sure which to choose, learn more about installing packages.