Helping to integrate Spectral Predictors and Rescoring.
Project description
inSPIRE
in silico Spectral Predictor Informed REscoring
inSPIRE allows easy rescoring of MaxQuant, Mascot or PEAKS DB search results using spectral prediction. inSPIRE is primarily developed to use Prosit predicted spectra but can also use MS2PIP predictions. inSPIRE enables the prediction of MS2 spectra with Prosit without the need of a GPU and it can be run on a standard workstation or laptop.
inSPIRE Versions from previous publications
We continue to update and improve inSPIRE with new releases. However, all previous versions used for passed publications are available online. The following versions are relevant for reproducing the exact results of previous publications:
-
Use version 1.0 (with minor bug fixes in versions 1.1, 1.2, and 1.3) and python version 3.9 for exact version used in inSPIRE: An open-source tool for increased mass spectrometry identification rates using Prosit spectral prediction
-
Use version 1.5 and python version 3.9 for the exact version used in Protein degradation by human 20S proteasomes elucidates the interplay between peptide hydrolysis and splicing
-
Use version 2.0rc6 and python version 3.11 for the latest inSPIRE functionality (manuscript in preparation).
Set Up
Before Downloading
If you are working on Mac with an M1 chip you will require Miniforge. For all other users, any version of conda will suffice.
Setting up your environment:
- To start with create a new conda environment with python version 3.11:
conda create --name inspire python=3.11
- Activate this environment
conda activate inspire
- You will then need to install the inspire package:
pip install inspirems==2.0rc8
- To check your installation, run the following command (it is normal for this call to hang for a few seconds on first execution)
inspire -h
- If you wish to use Percolator for rescoring rather than Mokapot you will need to install it separately. On Linux, Percolator can be installed via conda with the command below. Otherwise see https://github.com/percolator/percolator.
conda install -c bioconda percolator
Once you have successfully installed inSPIRE you should run it specifying your pipeline and a config file. The core execution of inSPIRE will take the form:
inspire --config_file path-to-config-file --pipeline pipeline-to-execute
where the config file is a yaml file specifying details of the inSPIRE execution and the pipeline is one of the options described below.
Citation
inSPIRE
Please cite the following article if you are using inSPIRE in your research:
Cormican, J. A., Horokhovskyi, Y., Soh, W. T., Mishto, M., and Liepe, J. (2022) inSPIRE: An open-source tool for increased mass spectrometry identification rates using Prosit spectral prediction. Mol Cell Proteomics.
doi.org/10.1016/j.mcpro.2022.100432
If you are using inSPIRE for analysis of in vitro protein digestions please cite the following article:
Soh, W. T., Roetschke, H. P., Cormican, J. A., Teo, B. F., Chiam, N. C., Raabe, M., Pflanz, R., Henneberg, F., Becker, S., Chari, A., Liu, H., Urlaub, H., Liepe, J., and Mishto, M. (2024) Protein degradation by human 20S proteasomes elucidates the interplay between peptide hydrolysis and splicing. Nature Communications.
doi.org/10.1038/s41467-024-45339-3
Dependencies
Please also cite the relevant publications of the rescoring tools used, see details on https://github.com/percolator/percolator if using Percolator and details on https://github.com/wfondrie/mokapot if using Mokapot.
Please also cite the relevant publications of the spectral predictors, see details on https://www.proteomicsdb.org/prosit if using Prosit and details on https://github.com/compomics/ms2pip_c if using MS2PIP.
If using inSPIRE-affinity please also cite the relevant publications for NetMHCpan binding affinity predictions. See details on https://services.healthtech.dtu.dk/service.php?NetMHCpan-4.1.
Running a small example.
The example folder provides a simple example that you should be able to run immediately.
inspire --pipeline downloadExample
The "core" pipeline which takes search engine and mgf input and produces fully rescored identifications using Prosit prediction on CPU. Execute this with:
inspire --pipeline core --config_file example/config.yml
This will run the rescoring and produce a report upon completion (this should take 2-3 minutes). This uses Mokapot rather than Percolator as it is easier to install together with inSPIRE. If you have Percolator installed and with to use it you can change the "rescoreMethod" in example/config.yml
Plotting Spectra
To use the inSPIRE plotting and see example pair plots comparing the experimental data to prosit predictions call:
inspire --pipeline plotSpectra --config_file example/config.yml
This plots the PSMs specified in example/output/plotData.csv and saves the plots to example/output/spectralPlots.pdf. To generate these plots for a different PSM simply copy the first 4 columns of the relevant line from example/output/finalAssignments.csv into example/output/finalAssignments.csv and rerun the plotSpectra pipeline.
inSPIRE-affinity
The core inSPIRE functionality can be executed via the "core" pipeline which will run rescoring using predicted spectra and provide final results to the user. If you wish to integrate binding affinity prediction you will have to make two modifications.
Firstly, you will need to add:
useBindingAffinity: asFeature
to your config.yml file.
Secondly, the execution will be slightly different. You will have to run two subsections of the "core" pipeline separately.
Firstly running the "prepare" pipeline will provide the input for all predictors. It will have created an mhcpan folder in the output folder with all unique peptides of each length saved as "inputLen{length}.txt". These can then be input to NetMHCpan (see https://services.healthtech.dtu.dk/service.php?NetMHCpan-4.1). The prediction files should be placed in the mhcpan folder as "outputLen{length}preds.txt".
You can then run the "predictSpectra" pipeline, followed by the "rescore" pipeline which will use the predicted binding affinities together with the spectral predictions to produce rescored PSM assignments.
inSPIRE for in vitro protein digestion.
If using inSPIRE for in vitro protein digestion after MSFragger search please use the following settings to your config file. Firstly to ensure that the FASTA headers of your spliced peptide database match those generated by invitroSPI and set this as the accession format.
accessionFormat: invitroSPI
Secondly, set this flag so that inSPIRE will use accession as a feature:
useAccessionStrata: True
Thirdly, please provide the protein sequence in FASTA format which is used for validation within inSPIRE:
proteome: path-to-fasta-file
Finally, for the less diverse dataset of the in vitro digestion, we also recommend using a minimal feature set to avoid overfitting:
useMinimalFeatures: True
Prosit Collision Energy Calibration
Prosit uses the collision energy setting of the mass spectrometer as input for MS2 prediction. While you could base this off the machine calibration, best results are expected if you callibrate prosit predictions for high scoring PSMs to the experimental data. Calibration will be executed automatically as part of the "core" pipeline if no collision energy is provided.
inSPIRE Config File
The configuration file is used to control inSPIRE execution using a set of keys and values specified in yaml format. yaml is a relatively simple format for entering many configs. The yaml file should take the form:
---
key1: value1
key2: value2
...
The keys needed are detailed below.
Required Configs
These are the minimal configs required to run inSPIRE.
Key | Description |
---|---|
experimentTitle | A title for the experiment. |
searchResults | The file path to the results of your ms search or a list of file paths if using multiple search results. |
searchEngine | The search engine used (maxquant, mascot, or peaks). |
outputFolder | Specify an output folder location which inSPIRE should write to. |
scansFolder | Specify a folder containing the experimental spectra files in mgf or mzML format. |
scansFormat | Specify the format of the spectra file (must be either mgf or mzML). |
Arguments Required for Prosit
Key | Description |
---|---|
collisionEnergy | The mass spectrometer collision energy setting (run --calibrate pipeline to estimate the optimal setting). |
deltaMethod | Recommended to set to "predictor" for immunopeptidome or "ignore" for tryptic proteome digestion. This defaults to ignore if MS2PIP is used. |
Arguments Required for MS2PIP Required
Key | Description |
---|---|
ms2pipModel | Specify the MS2PIP model to be used (recommended HCD2021 for tryptic proteome data and Immuno-HCD for immunopeptidome). |
Optional Settings (Experiment Specifications, Recommended to Check)
The following settings are set by default but you should check that they are valid for your experimental set up.
Key | Description |
---|---|
spectralPredictor | Either Prosit or MS2PIP (default=prosit). |
mzUnits | The units used for the m/z accuracy either Da for Daltons or ppm for Parts Per Million (default=Da). |
mzAccuracy | The mz accuracy of the mass spectrometer in Daltons or ppm(default=0.02, default unit is Da). |
rescoreMethod | inSPIRE supports either "mokapot" or "percolator" (default=mokapot). |
nCores | The number of CPU cores you wish to use in rescoring (default=1). |
fixedModifications | You must specify the fixed modifications used in a MaxQuant search. |
forceReload | Boolean flag on whether to force models to be redownloaded in case you accidentally change the contents of your inSPIRE model folder. |
Additional Options
These setting are optional and are completely dependent on user preference.
Key | Description |
---|---|
falseDiscoveryRate | This is the false discovery rate Percolator optimises for (default=0.01). |
excludeFeatures | This specifies any features which you wish to exclude from rescoring (default=empty list). |
includeFeatures | This specifies any features which you wish to include from rescoring and ignore all other features (default=empty list, meaning all features are used). |
reduce | By default inSPIRE uses only the highest scoring hit per scan (and accession group if specified). If you set reduce to False this will consider all hits (default=True). |
reuseInput | Boolean flag on whether to reuse formatted data after the first read in. When using Mascot in particular this may be useful as it reduces the time spend formatting data for input. |
filterCysteine | Option to filter cysteins from rescoring if the sample contains unmodified cysteine and Prosit is being used. |
dropUnknownPTMs | Whether to drop PSMs containing modifications other than oxidation of methionine and carbamidomethylation of cysteine. (default=True if prosit used, False if ms2pip used) |
Additional Configs for Mascot Distiller
If you have a combined mgf file from Mascot Distiller, you must add the following configs.
Key | Description |
---|---|
sourceFileName | If you are using a Mascot search from an mgf file which does not contain the source file name specify it here. |
scanTitleFormat | If Distiller used, set this argument to mascotDistiller. |
distillerLog | If Distiller used, set this argument to the path to the "table_peptide_int.txt" file from Distiller. |
combinedScansFile | Set this to the combined mgf file from Mascot Distiller and put the mgf file in folder specified by scansFolder. |
NetMHCpan Configs
NetMHCpan predicts the binding affinity of a peptide for various HLA molecules. inSPIRE can use this as a validation of its predictions or as a feature for rescoring.
Key | Description |
---|---|
useBindingAffinity | Set to asValidation if you want to check the percentage binders in your standard inSPIRE identifications. Set to asFeature if you want to use predicted binding affinity as a rescoring feature. |
inSPIRE Pipelines.
This section details all possible pipeline you can run with inSPIRE. The 3 most important pipelines are calibrate, core, and plotSpectra.
inspire --pipeline calibrate
As described above, this pipeline selects the highest scoring PSMs from the original search results and tests collision energy settings in the range 24 to 36 (inclusive) to find the optimal setting to be used. The calibrate collision energy is printed to the terminal.
inspire --pipeline core
The core pipeline reads in and formats the search results file, predicts MS2 spectra for the peptides, and runs rescoring to provide final identifications of all peptides.
This pipeline can be executed in a number of sub-sections as detailed below.
inspire --pipeline plotSpectra
This pipeline will plot experimental vs. Prosit predicted spectra for all PSMs specified in the plotData.csv file which should be placed in the output folder. This must at minimum specify the source file, scan number, peptide sequence, and modified sequence as provided in the inSPIRE finalAssignments.csv file.
Subsections of the core pipeline
The "core" pipeline contains a large number of steps, which can be run individually. This can be important when using the binding affinity prediction (see above) but also allows the user to make minor changes to the config file and rerun only the relevant sections of the pipeline.
inspire --pipeline prepare
This is the first step of the "core" functionality. It reads in the search results and formats input for Prosit/MS2PIP predictions and NetMHCpan if required.
inspire --pipeline predictSpectra
This predicts MS2 spectra using the specified spectral predictor and writes to msp format.
inspire --pipeline rescore
This option executes all of the remaining steps of the pipeline.
inspire --pipeline featureGeneration
This pipeline generate
inspire --pipeline featureSelection+
This pipeline filters the feature set as required by the config file (default does not apply any filter), runs rescoring, formats the output, and generates a html report with details of performance and comparison to a baseline rescoring without spectral prediction.
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