A Python package used to analysis Protein Sequence Activity Relationships
Project description
pySAR
Table of Contents
Introduction
pySAR is a Python library for analysing Sequence Activity Relationships (SARs) 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. The software uses physiochemical and biochemical features from the Amino Acid Index (AAI) database as well as allowing for the calculation of a range of structural protein descriptors.
After finding the optimal technique and feature set at which to encode your dataset of sequences, pySAR can then be used to build a predictive regression model with the training data being that of the encoded sequences, and training labels being the 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 and Directed Evolution, where a user has a set of experimentally determined activity values for a library of mutant protein sequences and wants to computationally predict the sought activity value for a selection of mutated sequences, in the aim of finding the best sequence that minimises/maximises their activity value.
Requirements
- Python >= 3.6
- numpy >= 1.16.0
- pandas >= 1.1.0
- sklearn >= 0.24
- scipy >= 1.4.1
- tqdm >= 4.55.0
- seaborn >= 0.11.1
Installation
Install the latest version of pySAR using pip:
pip3 install pySAR
Install by cloning repository:
git clone https://github.com/amckenna41/pySAR.git
python3 setup.py install
Usage
Generate 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 dataset set by desc_dataset input parameter. Output will be of the shape N x 9920, where N is the number of protein sequences in the dataset and 9920 is the total number of features calculated from all 15 descriptors. Setting all_desc parameter to True means all descriptors will be calculated, by default this is False.
from pySAR.descriptors import *
#calculating all descriptor values and storing in file named 'descriptors.csv'
# all_desc = True means that all descriptors will be calculated, False by default.
desc = Descriptor(protein_seqs=array_of_pro_sequences, desc_dataset="descriptors.csv",
all_desc=True)
Get record from AAIndex database
The AAIndex class offers diverse functionalities for obtaining any element from any record in the database. Each record is stored in json format in a class attribute called aaindex_json. You can search for a particular record by its index code, description or reference. You can also get the index category, and importantly its associated amino acid values.
import pySAR.aaindex as aaindex #import aaindex module from pySAR
#create AAIndex object
aai = aaindex.AAIndex()
record = aai.get_record_from_code('CHOP780206') #get full AAI record
category = aai.get_category_from_record('CHOP780206') #get record's category
values = aai.get_values_from_record('CHOP780206') #get amino acid values from record
refs = aai.get_ref_from_record('CHOP780206') #get references from record
num_record = aai.get_num_records() #get total number of records
record_names = aai.get_record_names() #get list of all record names
Encoding using all 566 AAIndex indices
Encoding protein sequences in dataset using all 566 indices in the AAI 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 model that can be used for accurate prediction of the sought activity 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 *
#create instance of Encoding class, inherits from pySAR class, using RandomForest algorithm
# with 200 estimators and a max_depth of 50.
encoding = Encoding(dataset="dataset.txt", activity="activity_col",
algorithm="RandomForest", parameters={"n_estimators":"200","max_depth":"50"})
#encode sequences using all indices in the AAI
aai_encoding = encoding.aai_encoding(spectrum='imaginary', window='blackman')
Output results showing AAI index and its category as well as all the associated metric values for each predictive model:
Index | Category | R2 | RMSE | MSE | RPD | MAE | Explained Var | |
---|---|---|---|---|---|---|---|---|
0 | CHOP780206 | sec_struct | 0.62737 | 3.85619 | 14.8702 | 1.63818 | 3.16755 | 0.713467 |
1 | QIAN880131 | sec_struct | 0.626689 | 3.90576 | 15.255 | 1.63668 | 3.09849 | 0.631582 |
2 | QIAN880118 | sec_struct | 0.625156 | 3.99581 | 15.9665 | 1.63333 | 3.32038 | 0.625897 |
3 | PRAM900104 | sec_struct | 0.615866 | 3.90389 | 15.2403 | 1.61346 | 3.24906 | 0.617799 |
.. | .......... | .......... | ........ | ....... | ....... | ....... | ....... | ............... |
Encoding using list of 4 AAI indices, with no DSP functionalities
Same procedure as prior, 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 input 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 *
#create instance of Encoding class, using PLS algorithm with its default params
encoding = Encoding(dataset="dataset.txt", activity="activity_col",
algorithm="PLSRegression", parameters={})
#encode sequences using 4 indices specified by user, use_dsp = False
aai_encoding = encoding.aai_encoding(use_dsp=False, aai_list=["PONP800102","RICJ880102","ROBB760107","KARS160113"])
Output DataFrame showing the 4 predictive models built using the PLS algorithm, with the 4 indices from the AAI:
Index | Category | R2 | RMSE | MSE | RPD | MAE | Explained Var | |
---|---|---|---|---|---|---|---|---|
0 | PONP800102 | hydrophobic | 0.74726 | 3.0817 | 9.49688 | 1.98913 | 2.63742 | 0.751032 |
1 | ROBB760107 | sec_struct | 0.666527 | 3.19801 | 10.2273 | 1.73169 | 2.50305 | 0.668255 |
2 | RICJ880102 | sec_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 their calculated protein descriptors
Calculate the protein descriptor values for a dataset of protein sequences from the 15 available descriptors in the descriptors module. Use each descriptor as a feature set in the building of the predictive models used to predict the activity value of unseen sequences. By default, function will look for a file called 'descriptors.csv' that contains the pre-calculated descriptor values for a dataset, this filename can be changed according to the descriptors_csv input parameter, if file is not found then all descriptor values will be calculated for the dataset.
from pySAR.encoding import *
#create instance of Encoding class using AdaBoost algorithm, using 100 estimators & a learning rate of 1.5
encoding = Encoding(dataset="dataset.txt", activity="activity_col",algorithm="AdaBoost",
parameters={"n_estimators":100,"learning_rate":1.5}, descriptors_csv="descriptors.csv")
#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:
Descriptor | Group | R2 | RMSE | MSE | RPD | MAE | Explained Var | |
---|---|---|---|---|---|---|---|---|
0 | _distribution | 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 | _aa_composition | Composition | 0.612824 | 3.37447 | 11.3871 | 1.60711 | 2.79698 | 0.643864 |
4 | ...... | ...... | ...... | ...... | ...... | ...... | ...... | ...... |
Building predictive model from AAI and protein descriptors:
e.g: 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 model.
import pySAR as pysar #import pySAR package
#create instance of PySAR class
pySAR = pysar.PySAR(dataset="dataset.txt",activity="activity",algorithm="PlsRegression")
"""
PySAR parameters:
dataset : str (default = "")
full path to dataset or name of dataset if it is stored in DATA_DIR.
seq_col : str (default = "sequence")
name of column in dataset that stores the protein sequences. By default
the class will look for a column called 'sequence'.
activity : str (default = "")
name of activity column in dataset.
algorithm : str (default = "")
name of regression model to use for building the predictive models, class
will accept full name or approximate name of model e.g "PLSReg", "plsregg" and
"PLSRegression" will all build a PlsRegression model.
parameters : dict (default = {})
dictionary of parameters to use for the predictive model. By default the
default parameters of the model will be used.
test_split : float (default = 0.2)
specifies the proportion of the dataset to use for testing. By default a
80:20 split will be used, meaning 80% of the data will be used for training
and 20% for testing.
descriptors_csv : str (default = "descriptors.csv")
csv file storing the pre-calculated descriptor values for the sequences
in the dataset. By default the class will look for a file named
"descriptors.csv" in the DATA_DIR and will use its contents as the
descriptor features, instead of having to recalculate all descriptors for the dataset.
"""
#encode protein sequences using both the CIDH920105 index + aa_composition descriptor.
results_df = pySAR.encode_aai_desc(indices="CIDH920105", descriptors="aa_composition",
spectrum="power", window="hamming")
Encoding using AAI + protein descriptors
Encoding protein sequences in dataset using all 566 indices in the AAI database combined with protein descriptors. All 566 indices can be used in concatenation with 1, 2 or 3 descriptors. E.g: at each iteration the encoded sequences using the indices from the AAI will be used to generate a protein spectra using the power spectrum with no window function applied, this will then be combined with the feature set generated from the dataset's descriptor values and used to build a predictive model that can be used for accurate prediction of the sought activity 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 *
#create instance of Encoding class using RF algorithm, using 100 estimators with a learning rate of 1.5
encoding = Encoding(dataset="dataset.txt", activity="activity_col",algorithm="AdaBoost",
parameters={"n_estimators":100,"learning_rate":1.5}, descriptors_csv="descriptors.csv")
#building predictive models using all available aa_indices + combination of 2 descriptors,
# calculating evaluation metric values for models and storing into aai_desc_results_df DataFrame
aai_desc_results_df = encoding.aai_descriptor_encoding(desc_combo=2, spectrum='power', window=None)
Output results showing AAI index and its category, the protein descriptor and its group as well as the R2 and RMSE values for each predictive model:
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 | ..... | ..... | ..... | ..... | ..... | ..... |
Research Article
The research article that accompanied this software is: "Comparative study on the utility of protein spectra and protein descriptors in the analysis of sequence activity relationships". This research article is uploaded to the repository as pySAR_research.pdf
Directories
/pySAR/PyBioMed
- package partially forked from https://github.com/gadsbyfly/PyBioMed, used in the calculation of the protein descriptors./Results
- stores all calculated results that were generated for the research article, studying the SAR for a thermostability dataset./pySAR/tests
- unit and integration tests for pySAR./pySAR/data
- all required data and datasets are stored in this folder.
Tests
To run all tests, from the main pySAR folder run:
python3 -m unittest discover
To run tests for specific module, from the main pySAR folder run:
python -m unittest tests.MODULE_NAME -v
Contact
If you have any questions or comments, please contact amckenna41@qub.ac.uk or raise an issue on the Issues tab.
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