pySAR is a Python library for analysing Sequence Activity Relationships (SARs)/Sequence Function Relationships (SFRs) of protein sequences.
- 📖 The published research article is available here.
- 🌍 A front-end app for
pySARis available [here][frontend] (coming soon). - 💻 A quick Colab notebook demo of
pySARis available here. - 📰 A Medium article that dives deeper into SARs and the
pySARsoftware itself is available here.
- Introduction
- Background
- Requirements
- Installation
- Documentation
- Usage
- Directories
- Issues
- Contact
- License
- References
The research article that accompanied this software is titled: Machine Learning Based Predictive Model for the Analysis of Sequence Activity Relationships Using Protein Spectra and Protein Descriptors and was published in the Journal of Biomedical Informatics[1].
Mckenna, A., & Dubey, S. (2022). Machine learning based predictive model for the analysis of sequence activity relationships using protein spectra and protein descriptors. Journal of Biomedical Informatics, 128(104016), 104016. https://doi.org/10.1016/j.jbi.2022.104016
pySAR is a Python library for analysing Sequence Activity Relationships (SARs)/Sequence Function Relationships (SFRs) of protein sequences. pySAR offers extensive and verbose functionalities that allow you to numerically encode a dataset of protein sequences using a large abundance of available methodologies and features, supporting 400,000+ different encoding strategies. The software uses physicochemical and biochemical features from the Amino Acid Index (AAI) database [2] via the custom-built aaindex package, as well as allowing for the calculation of a range of structural, physicochemical and biochemical protein descriptors via the custom-built protpy package.
After finding the optimal technique and feature set at which to numerically encode your dataset of sequences, pySAR can then be used to build a predictive regression ML model with the training data being that of the encoded protein sequences, and the training labels being the in vitro experimentally pre-calculated activity values for each protein sequence. This model maps a set of protein sequences to the sought-after activity value, being able to accurately predict the activity/fitness value of new unseen sequences. The use-case for the software is within the field of Protein Engineering, Directed Evolution and or Drug Discovery, where a user has a set of in vitro experimentally determined activity/fitness values for a library of mutant protein sequences and wants to computationally predict the sought activity value for a selection of mutated unseen sequences, in the aim of finding the best sequence that minimises/maximises their activity value.
In the published research, the sought activity/fitness characteristic is the thermostability of proteins from a recombination library designed from parental cytochrome P450's. This thermostability is measured using the T50 metric (temperature at which 50% of a protein is irreversibly denatured after 10 mins of incubation, ranging from 39.2 to 64.4 degrees C), which we want to maximise [1].
Two additional custom-built softwares were created alongside pySAR - aaindex and protpy. The aaindex software package is used for parsing the amino acid index which is a database of numerical indices representing various physicochemical and biochemical properties of amino acids and pairs of amino acids [2]. protpy is used for calculating a series of protein physicochemical, biochemical and structural protein descriptors. Both of these software packages are integrated into pySAR but can also be used individually for their respective purposes.
Accurately establishing the connection between a protein sequence and its function remains a focal point within the fields of proteomics, protein engineering and drug discovery. There has been a continued drive to build accurate and reliable predictive models via Machine Learning (ML) that allow for the virtual screening of many protein mutant sequences, measuring the relationship between sequence and 'fitness' or 'activity' — commonly known as a Sequence-Activity-Relationship (SAR) or Sequence-Function-Relationship (SFR). Due to the cost and impracticality of experimentally measuring these activity/fitness values for large libraries of mutant sequences, it is of great benefit to accelerate and automate this process computationally.
An important preliminary stage in the building of these predictive models is the numerical encoding of the chosen protein sequences, as sequences and their constituent amino acids cannot be directly passed into ML models. pySAR primarily focuses on encoding strategies involving the Amino Acid Index database and a variety of sequence-derived physicochemical and biochemical descriptors. Taking into account the various combinations of features and descriptors, pySAR supports 400,000+ different encoding strategies.
Directed Evolution (DE) is a prominent real-world use-case: a methodology for protein engineering that mimics natural selection, optimising a protein through iterative rounds of mutagenesis, selection, and amplification. pySAR can support such workflows by computationally predicting which mutant sequences are most likely to yield the desired activity value — reducing the burden of wet-lab experimentation.
- python >= 3.8
- aaindex >= 1.2.0
- protpy >= 1.3.0
- numpy >= 1.21
- pandas >= 1.3
- scikit-learn >= 1.0
- scipy >= 1.7
- delayed >= 0.11
- tqdm >= 4.60
- matplotlib >= 3.4
- seaborn >= 0.11
Install the latest version of pySAR via PyPi using pip:
pip3 install pysar --upgradeInstallation from source:
git clone -b master https://github.com/amckenna41/pySAR.git
cd pySAR
pip3 install .Full documentation for pySAR is available on Read the Docs, including:
pySAR works mainly via JSON configuration files. There are many different customisable parameters for the functionalities in pySAR including the metaparameters of some of the available protein descriptors, all Digital Signal Processing (DSP) parameters in the pyDSP module, the type of regression model to use and parameters specific to the dataset - a description of each parameter is available on the CONFIG.md file.
These config files offer a more straightforward way of making any changes to the pySAR pipeline. The names of All the parameters as listed in the example config files must remain unchanged, only the value of each parameter should be changed, any parameters not being used can be set to null. Additionally, you can pass in the individual parameter names and values to the pySAR and Encoding classes when numerically encoding the protein sequences via kwargs. An example of the config file used in my research project (thermostability.json), with most of the available parameters, can be seen below and in the example config file - CONFIG.md.
{
"dataset":
{
"dataset": "thermostability.txt",
"sequence_col": "sequence",
"activity": "T50"
},
"model":
{
"algorithm": "plsregression",
"parameters": "",
"test_split": 0.2
},
"descriptors":
{
"descriptors_csv": "descriptors_thermostability.csv",
"moreaubroto_autocorrelation":
{
"lag":30,
"properties":["CIDH920105", "BHAR880101", "CHAM820101", "CHAM820102",
"CHOC760101", "BIGC670101", "CHAM810101", "DAYM780201"],
"normalize": 1
},
...
},
"pyDSP":
{
"use_dsp": 1,
"spectrum": "power",
"window": {
"type": "hamming",
...
},
"filter": {
"type": null,
...
}
}
}Encoding protein sequences using all 566 AAIndex indices:
Encoding protein sequences in dataset using all 566 indices in the AAI1 database. Each sequence encoded via an index in the AAI can be passed through an additional step where its protein spectra can be generated following an FFT. pySAR supports generation of the power, imaginary, real or absolute spectra as well as other DSP functionalities including windowing and filter functions.
In the example below, the encoded sequences will be used to generate a imaginary protein spectra with a blackman window function applied. This will then be used as feature data to build a predictive regression ML model that can be used for accurate prediction of the sought activity value (thermostability) of unseen protein sequences. The encoding class also takes the JSON config file as input which will have all the required parameter values. The output results will show the calculated metric values for each index in the AAI when measuring predicted vs observed activity values for the unseen test sequences.
from pySAR.encoding import Encoding
'''thermostability.json
{
"dataset":
{
"dataset": "thermostability.txt",
"activity": "T50"
...
}
"model":
{
"algorithm": "randomforest",
...
}
"pyDSP":
{
"use_dsp": 1,
"spectrum": "imaginary",
"window": {
"type": "blackman"
}
}
}
'''
#create instance of Encoding class, using RF algorithm with its default params
encoding = Encoding(config_file='thermostability.json')
#encode sequences using all indices in the AAI if input parameter "aai_indices" is empty/None
aai_encoding = encoding.aai_encoding()Output results showing AAI index and its category as well as all the associated metric values for each predictive model. From the results below we can determine that the CHOP780206 index in the AAI has the highest predictability (R2 score) for our chosen dataset (thermostability) and this generated model can be used for predicting the thermostability of new unseen sequences:
| Index | Category | R2 | RMSE | MSE | RPD | MAE | Explained Variance | |
|---|---|---|---|---|---|---|---|---|
| 0 | CHOP780206 | secondary_struct | 0.62737 | 3.85619 | 14.8702 | 1.63818 | 3.16755 | 0.713467 |
| 1 | QIAN880131 | secondary_struct | 0.626689 | 3.90576 | 15.255 | 1.63668 | 3.09849 | 0.631582 |
| 2 | QIAN880118 | secondary_struct | 0.625156 | 3.99581 | 15.9665 | 1.63333 | 3.32038 | 0.625897 |
| 3 | PRAM900104 | secondary_struct | 0.615866 | 3.90389 | 15.2403 | 1.61346 | 3.24906 | 0.617799 |
| .. | .......... | .......... | ........ | ....... | ....... | ....... | ....... | ........... |
Encoding using list of 4 AAI indices, with no DSP functionalities:
This method follows a similar procedure as the previous step, except 4 indices from the AAI are being specifically input into the function, with the encoded sequence output being concatenated together and used as feature data to build the predictive PLSRegression model with its default parameters. The config parameter use_dsp tells the function to not generate the protein spectra or apply any additional DSP processing to the sequences.
from pySAR.encoding import Encoding
'''thermostability.json
{
"dataset":
{
"dataset": "thermostability.txt",
"activity": "T50"
...
}
"model":
{
"algorithm": "plsreg",
"parameters": null
}
"pyDSP":
{
"use_dsp": 0,
...
}
}
'''
#create instance of Encoding class, using PLS algorithm with its default params
encoding = Encoding(config_file='thermostability.json')
#encode sequences using 4 indices specified by user, use_dsp = False
aai_encoding = encoding.aai_encoding(aai_indices=["PONP800102","RICJ880102","ROBB760107","KARS160113"])Output DataFrame showing the 4 predictive models built using the PLS algorithm, with the 4 indices from the AAI. From the results below we can determine that the PONP800102 index in the AAI has the highest predictability (R2 score) for our chosen dataset (thermostability) and this generated model can be used for predicting the thermostability of unseen sequences:
| Index | Category | R2 | RMSE | MSE | RPD | MAE | Explained Variance | |
|---|---|---|---|---|---|---|---|---|
| 0 | PONP800102 | hydrophobic | 0.74726 | 3.0817 | 9.49688 | 1.98913 | 2.63742 | 0.751032 |
| 1 | ROBB760107 | secondary_struct | 0.666527 | 3.19801 | 10.2273 | 1.73169 | 2.50305 | 0.668255 |
| 2 | RICJ880102 | secondary_struct | 0.568067 | 3.83976 | 14.7438 | 1.52157 | 3.01342 | 0.568274 |
| 3 | KARS160113 | meta | 0.544129 | 4.04266 | 16.3431 | 1.48108 | 3.26047 | 0.544693 |
Encoding protein sequences using all available protein descriptors:
Calculate the protein descriptor values for a dataset of protein sequences from the 33 available descriptors in the descriptors module. Use each descriptor as a feature set in the building of the predictive ML models used to predict the activity value of unseen sequences. By default, the function will look for a csv file pointed to by the "descriptors_csv" parameter in the config file that contains the pre-calculated descriptor values for a dataset. If file is not found then all descriptor values will be calculated for the dataset using the descriptors module and custom-built protpy package.
from pySAR.encoding import Encoding
'''thermostability.json
{
"dataset":
{
"dataset": "thermostability.txt",
"activity": "T50"
...
}
"model":
{
"algorithm": "adaboost",
"parameters": [{
"estimators": 100,
"learning_rate": 1.5
...
},
"descriptors":
{
"descriptors_csv": "descriptors_thermostability.csv",
"moreaubroto_autocorrelation": {
"lag": 30,
"properties": ["CIDH920105", "BHAR880101", "CHAM820101", "CHAM820102",
"CHOC760101", "BIGC670101", "CHAM810101", "DAYM780201"],
"normalize": 1
},
...
}
}
'''
#create instance of Encoding class using AdaBoost algorithm, using 100 estimators & a learning rate of 1.5
encoding = Encoding(config_file='thermostability.json')
#building predictive models using all available descriptors, calculating evaluation metrics values for
# models and storing into desc_results_df DataFrame
desc_results_df = encoding.descriptor_encoding()Output results showing the protein descriptor and its group as well as all the associated metric values for each predictive model. From the results below we can determine that the CTD Distribution descriptor has the highest predictability (R2 score) for our chosen dataset (thermostability) and this generated model can be used for predicting the thermostability of unseen sequences:
| Descriptor | Group | R2 | RMSE | MSE | RPD | MAE | Explained Variance | |
|---|---|---|---|---|---|---|---|---|
| 0 | ctd_d | CTD | 0.721885 | 3.26159 | 10.638 | 1.89621 | 2.60679 | 0.727389 |
| 1 | geary_autocorrelation | Autocorrelation | 0.648121 | 3.67418 | 13.4996 | 1.68579 | 2.82868 | 0.666745 |
| 2 | tripeptide_composition | Composition | 0.616577 | 3.3979 | 11.5457 | 1.61496 | 2.53736 | 0.675571 |
| 3 | amino_acid_composition | Composition | 0.612824 | 3.37447 | 11.3871 | 1.60711 | 2.79698 | 0.643864 |
| 4 | ...... | ...... | ...... | ...... | ...... | ...... | ...... | ...... |
Encoding using AAI + protein descriptors:
Encoding protein sequences in the dataset using ALL 566 indices in the AAI database combined with ALL available protein descriptors. All 566 indices can be used in concatenation with 1, 2 or 3 descriptors. At each iteration the encoded sequences generated from the indices from the AAI will be combined with the feature set generated from the dataset's descriptor values and used to build a predictive regression ML model that can be used for the accurate prediction of the sought activity/fitness value of unseen protein sequences. The output results will show the calculated metric values when measuring predicted vs observed activity values for the test sequences.
from pySAR.encoding import Encoding
'''thermostability.json
{
"dataset":
{
"dataset": "thermostability.txt",
"activity": "T50"
...
}
"model":
{
"algorithm": "randomforest",
"parameters":
{
"estimators": 100,
"learning_rate": 1.5,
...
}
},
"descriptors":
{
"descriptors_csv": "descriptors_thermostability.csv",
"moreaubroto_autocorrelation": {
"lag": 30,
"properties": ["CIDH920105", "BHAR880101", "CHAM820101", "CHAM820102",
"CHOC760101", "BIGC670101", "CHAM810101", "DAYM780201"],
"normalize": 1
},
...
},
"pyDSP":
{
"use_dsp": 0,
"spectrum": "power",
"window": ""
...
}
}
'''
#create instance of Encoding class using RF algorithm, using 100 estimators with a learning rate of 1.5 - as listed in config
encoding = Encoding('thermostability.json')
#building predictive models using all available aa_indices + descriptors, calculating evaluation metric values for models and storing into aai_desc_results_df DataFrame
aai_desc_results_df = encoding.aai_descriptor_encoding()Output results showing AAI index and its category, the protein descriptor and its group as well as all output metric values for each predictive model. From the results below we can determine that the ARGP820103 index in concatenation with the Conjoint Triad descriptor has the highest predictability (R2 score) for our chosen dataset (thermostability) and this generated model can be used for predicting the thermostability of unseen sequences:
| Index | Category | Descriptor | Descriptor Group | R2 | RMSE | |
|---|---|---|---|---|---|---|
| 0 | ARGP820103 | composition | _conjoint_triad | Conjoint Triad | 0.72754 | 3.22135 |
| 1 | ARGP820101 | hydrophobic | _quasi_seq_order | Quasi-Sequence-Order | 0.722284 | 3.30995 |
| 2 | ARGP820101 | hydrophobic | _seq_order_coupling_number | Quasi-Sequence-Order | 0.722158 | 3.34926 |
| 3 | ANDN920101 | observable | _seq_order_coupling_number | Quasi-Sequence-Order | 0.70826 | 3.25232 |
| 4 | ..... | ..... | ..... | ..... | ..... | ..... |
Building predictive model from subset of AAI and protein descriptors:
The below code will build a PLSRegression model using the AAI index CIDH920105 and the amino acid composition descriptor. The index is passed through a DSP pipeline and is transformed into its informational protein spectra using the power spectra, with a hamming window function applied to the output of the FFT. The concatenated features from the AAI index and the descriptor will be used as the feature data in building the PLS ML model. This model is then used to access its predictability by testing on test unseen sequences. The output results will show the calculated metric values when measuring predicted vs observed activity values for the test sequences.
from pySAR.pySAR import PySAR
'''thermostability.json
{
"dataset":
{
"dataset": "thermostability.txt",
"activity": "T50"
...
},
"model":
{
"algorithm": "plsregression",
"parameters": "",
...
},
"descriptors":
{
"descriptors_csv": "descriptors_thermostability.csv",
"moreaubroto_autocorrelation": {
"lag": 30,
"properties": ["CIDH920105", "BHAR880101", "CHAM820101", "CHAM820102",
"CHOC760101", "BIGC670101", "CHAM810101", "DAYM780201"],
"normalize": 1
},
...
},
"pyDSP":
{
"use_dsp": 1,
"spectrum": "power",
"window": "hamming",
...
}
}
'''
#create instance of PySAR class, inputting path to configuration file
pySAR = PySAR(config_file="thermostability.json")
#encode protein sequences using both the CIDH920105 index + aa_composition descriptor
results_df = pySAR.encode_aai_descriptor(aai_indices="CIDH920105", descriptors="amino_acid_composition")Output results showing AAI index and its category, the protein descriptor and its group as well as the metric values for the generated predictive model. From the results below we can determine that the CIDH920105 index in concatenation with the Amino Acid Composition descriptor has medium predictability (R2 score) but a high error rate (MSE/RMSE) for our chosen dataset (thermostability) and this feature set combination is not that effective for predicting the thermostability of unseen sequences:
##########################################################################################
###################################### Parameters ########################################
# AAI Indices: CIDH920105
# Descriptors: amino_acid_composition
# Configuration File: thermostability_config.json
# Dataset: thermostability.txt
# Number of Sequences/Sequence Length: 261 x 466
# Target Activity: T50
# Algorithm: PLSRegression
# Model Parameters: {'copy': True, 'max_iter': 500, 'n_components': 2, 'scale': True,
#'tol': 1e-06}
# Test Split: 0.2
# Feature Space: (261, 486)
##########################################################################################
######################################## Results #########################################
# R2: 0.6720111107323943
# RMSE: 3.7522525079464457
# MSE: 14.079398883390391
# MAE: 3.0713217158459805
# RPD 1.7461053136208489
# Explained Variance 0.6721157080699659
##########################################################################################Calculate individual descriptor values, e.g Tripeptide Composition and Geary Autocorrelation:
The individual protein descriptor values for the dataset of protein sequences can be calculated using the custom-built protpy package via the descriptor module. The full list of descriptors can be seen via the function all_descriptors_list() as well as on the protpy repo homepage.
from pySAR.descriptors import Descriptors
#create instance of descriptors class
desc = Descriptors(config_file="thermostability.json")
#calculate tripeptide composition descriptor
tripeptide_composition = desc.get_tripeptide_composition()
#calculate geary autocorrelation descriptor
geary_autocorrelation = desc.get_geary_autocorrelation()Calculate and export all protein descriptors:
Prior to evaluating the various available properties and features at which to encode a set of protein sequences, it is reccomened that you pre-calculate all the available descriptors in one go, saving them to a csv for later that pySAR will then import from. Output values are stored in a csv set by the descriptors_csv config parameter (the name of the exported csv via the descriptors_export_filename parameter can also be passed into the function). Output will be of the shape N x M, where N is the number of protein sequences in the dataset and M is the total number of features calculated from all 33 descriptors which varies depending on some descriptor-specific metaparameters. For example, using the thermostability dataset, the output will be 261 x 10572.
'''thermostability.json
{
"dataset":
{
"dataset": "thermostability.txt",
"activity": "T50"
...
},
"model":
{
...
}
"descriptors":
{
"descriptors_csv": "descriptors_thermostability.csv",
"moreaubroto_autocorrelation": {
"lag": 30,
"properties": ["CIDH920105", "BHAR880101", "CHAM820101", "CHAM820102",
"CHOC760101", "BIGC670101", "CHAM810101", "DAYM780201"],
"normalize": 1
},
...
},
"pyDSP":
{
...
}
}
'''
#import descriptors class
from pySAR.descriptors import Descriptors
#create instance of descriptors class
desc = Descriptors(config_file="thermostability.json")
#export all descriptors to csv using parameters in config, export=True will export to csv
desc.get_all_descriptors(export=True, descriptors_export_filename="descriptors_thermostability.csv")Get record from AAIndex database:
A custom-built package called aaindex was created for this project to work with all the data in the AAIndex databases, primarily the aaindex1. The AAIndex library offers diverse functionalities for obtaining all data from all records within the aaindex1. Each record is stored in json format and can be retrieved via its accession number, and can also be searched via its name/description. Each record contains the following attributes: description, references, category, notes, correlation coefficient, pmid and values.
from aaindex import aaindex1
record = aaindex1['CHOP780206'] #get full record
description = aaindex1['CHOP780206'].description #get record's description
refs = aaindex1['CHOP780206'].references #get record's references
category = aaindex1['CHOP780206'].category #get record's category
notes = aaindex1['CHOP780206'].notes #get record's notes
correlation_coefficients = aaindex1['CHOP780206'].correlation_coefficients #get record's correlation coefficients
pmid = aaindex1['CHOP780206'].pmid #get record's pmid
values = aaindex1['CHOP780206'].values #get amino acid values from record
num_record = aaindex1.num_records() #get total number of records
record_names = aaindex1.record_names() #get list of all record names
amino_acids = aaindex1.amino_acids() #get list of all canonical amino acids
records = aaindex1.search("hydrophobicity") #get all records with hydrophobicity in their title/descriptionParallel encoding across all AAI indices using n_jobs:
Setting
n_jobs to a value greater than 1 distributes model-building across multiple CPU cores. Pass n_jobs=-1 to use all available cores. This applies to all three encoding methods and can significantly reduce wall-clock time when evaluating hundreds of indices or descriptor combinations.from pySAR.encoding import Encoding, SortKey
encoding = Encoding(config_file='thermostability.json')
# build 566 AAI models in parallel using all CPU cores, sorted by RMSE
aai_results = encoding.aai_encoding(n_jobs=-1, sort_by=SortKey.RMSE)
# build all descriptor models in parallel using 4 workers
desc_results = encoding.descriptor_encoding(n_jobs=4)
# build AAI + descriptor models in parallel - can be many thousands of models
aai_desc_results = encoding.aai_descriptor_encoding(n_jobs=-1, max_models=1000)For reproducible parallel runs, pass random_state to seed the ML models:
aai_results = encoding.aai_encoding(n_jobs=-1, random_state=42)Resuming a partially-completed encoding run:
Long encoding jobs (e.g. all 566 AAI indices or thousands of AAI+descriptor combinations) can be interrupted and resumed without re-running completed models. Enable checkpointing by passing
resume=True and a path for the checkpoint file via resume_file. On the first run a checkpoint CSV is written after each batch; subsequent runs with the same file skip already-completed keys and append the new results.from pySAR.encoding import Encoding
encoding = Encoding(config_file='thermostability.json')
# first run - starts from scratch and saves progress to checkpoint.csv after each index
aai_results = encoding.aai_encoding(
resume=True,
resume_file='aai_checkpoint.csv',
n_jobs=4
)
# later run (e.g. after an interruption) - skips completed indices automatically
aai_results = encoding.aai_encoding(
resume=True,
resume_file='aai_checkpoint.csv',
n_jobs=4
)The same pattern works for descriptor_encoding and aai_descriptor_encoding:
aai_desc_results = encoding.aai_descriptor_encoding(
resume=True,
resume_file='aai_desc_checkpoint.csv',
n_jobs=-1
)Using descriptor validation and utility methods:
The
Descriptors class exposes several utility methods for validating inputs, inspecting descriptor metadata and managing internal state. These can be used independently of the main encoding workflow.from pySAR.descriptors import Descriptors, DescriptorType
from pySAR.descriptors import InvalidDescriptorError, InvalidSequenceError
desc = Descriptors(config_file='thermostability.json')
# validate a list of descriptor names - raises InvalidDescriptorError for unknown names
valid_descs = desc.validate_descriptors(['amino_acid_composition', 'dipeptide_composition'])
# validate sequences in the loaded dataset - raises InvalidSequenceError for non-canonical amino acids
desc.validate_sequences()
# retrieve metadata (feature count, group, and parameters) for a descriptor
info = desc.get_descriptor_info('amino_acid_composition')
print(info)
# {'name': 'amino_acid_composition', 'group': 'Composition', 'feature_count': 20, 'parameters': {}}
# get the total number of features produced by the current descriptor configuration (per descriptor)
total_features = desc.descriptor_feature_count # cached property; returns dict of {name: count}
# get the list of output column names for a specific descriptor (must be calculated first)
desc.get_amino_acid_composition() # calculate it first
cols = desc.get_descriptor_columns('amino_acid_composition')
# reset all descriptor DataFrames back to empty (useful before re-calculation workflows)
desc.reset_descriptors()
# clear the internal feature-count cache (e.g. after changing descriptor metaparameters)
desc.clear_cache()Use the DescriptorType enum to filter or identify descriptor families:
from pySAR.descriptors import DescriptorType
# enum members: COMPOSITION, AUTOCORRELATION, SEQUENCE_ORDER, PSEUDO_AA, CTD, CONJOINT_TRIAD
print(DescriptorType.COMPOSITION.value) # 'composition'/config- configuration files for the example datasets thatpySARhas been tested with, as well as the thermostability.json config file that was used in the research. These config files should be used as a template for future datasets used withpySAR./data- data files used in the research project including the thermostability dataset, config file and pre-calculated protein descriptors./docs- Sphinx documentation source forpySAR, includingconf.py,index.rst,usage.rst,api.rstandcontributing.rst./example_datasets- example datasets used for the building and testing ofpySAR, including the thermostability dataset used in the research. The format of these datasets should be used as a template for future datasets used withpySAR./images- all images used throughout the repo./pySAR- source code forpySARsoftware./tests- unit and integration tests forpySAR.pyproject.toml- package build metadata and dependency specification (PEP 517/518).CONFIG.md- example markdown file describing each of the available parameters in the config files.
Any issues, errors or bugs can be raised via the Issues tab in the repository.
If you have any questions or comments, please contact amckenna41@qub.ac.uk or raise an issue on the Issues tab.
Distributed under the MIT License. See LICENSE for more details.
[1]: Mckenna, A., & Dubey, S. (2022). Machine learning based predictive model for the analysis of sequence activity relationships using protein spectra and protein descriptors. Journal of Biomedical Informatics, 128(104016), 104016. https://doi.org/10.1016/j.jbi.2022.104016
[2]: Kawashima, S. and Kanehisa, M., 2000. AAindex: amino acid index database. Nucleic acids research, 28(1), pp.374-374. DOI: 10.1093/nar/27.1.368
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