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Automated pipeline to run all pep-seq code on simulated and raw data

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Pep-seq Pipeline

Automated pipeline to run all pep-seq code on simulated and raw data


Pipeline Components

The pep-seq pipeline puts together the 7 essential steps of finding a toxic motifs in a peptide library into a single program. It relies heavily on the code and data found in our original pep-seq repo as well as the code we wrote for the MotifFinder algorithm, but with a bash script and added stats tests which combines all the parts together and a more organized design.

There are 7 essential steps to our pipeline:

  1. Filter original protein library to try to reduce noise in the data
  2. Format the filtered protein library into an atribute relation file format to be used for further steps of the pipeline.
  3. Run the arff file through a Random Forest machine learning classifier using weka code
  4. Take the resulting the output of the Random Forest model and pipe it into our MotifFinder from a decision forest java code. Which will ouput a list of possible motifs which are most likely to be toxic/antitoxic/etc.
  5. Use the probable motifs found to cluster the data into groups peptides groups that match those motifs
  6. Use motif finding algorithms to find a consensus motif for each of the clusters
  7. Run statistical test on these consensus motifs to test if expression of that motif causes a statistically significant difference in antimicrobial activity of the peptide

1. FILTER:

Filter uses a python script to convert the original peptide library data into a new format that contains a nomializtion of the toxicity class. Its purpose is two-fold

  1. Get rid of data that has too much noise. The two main ways that we filter are by first checking to see if the toxicity score differs significantly between the two replicates. And second by tossing out replicates that contained too few data points in their sample. Peptides were also filtered out if the contianed one of the 8 underrepresented amino acid residues.
  2. Classify each of the peptide sequences as either toxic, antitoxic, or neutral. We calculated a toxicity score by adding up the replicates in the reference sample and dividing by sum of the replicates in the induced sample. We then found the std. deviation and all peptides greater than one std deviation were classified toxic, all those less than one std. deviation classified antitoxic, and those in between were classified as neutral.

2. FORMAT:

After the data has been filtered and classified. We convert the new filtered input data into the correct file format to be ran through a machine learning classifier. Weka requires that data be in an attribute relation file format (arff). And Step two of the pipeline runs the data through a python script to format this data correctly.

An optional step before formatting is to balance the data set. Based on how we defined toxic, antitoxic, and neutral classes, the nuetral peptides were significantly overrepresented. This can cause high bias in the machine learning classifiers (in the worst case, the learner classifies all peptides as neutral).To prevent this we can balance the data which will overrepresent data from the two minority classes and take a smaller random sample out of the neutral data. Use -b on the command line to run this balance script

3. CLASSIFY:

After the data has been formatted into an arff file. It is put into a Random Forest machine learning classifier so we can try to learn the patterns present in the data. To do this we use the Random Forest classifier in Weka (weka.classifiers.trees.RandomForest). We chose to use 500 iterations, a bagging size of 50%, random choice if there is a tie, and to allow for unclassified instances because these gave us the highest true positive and lowest false positive scores for our training set. The complete weka command we used is below:

java -cp dependency_jars/weka.jar weka.classifiers.trees.RandomForest -U -B -P 50 -I 500 -print -no-cv  -t $INPUT_FILE 

If the data is already in arff format, you can skip to this step by including the command line parameter --arff. It is also possible to run a normal decision tree instead of a random Forest by including the parameter --j48 which will run a j48 classifier instead of a random Forest. We recommend using random Forest because it helps prevent overfitting of the training set. But with extremely large datasets a j48 classifier will run much faster and be much more manageable.

4. FIND PARTIAL MOTIFS:

To find partial motifs we take the output of the Random Forest (or j48) classifier and traverse the tree to recreate the motifs the learner used to correctly classify the peptides. We use the MotifFinderDecisionTree java program that we created to do this. Full documentation on this program can be found at this link: https://github.com/tjense25/MotifFinderDecisionTree

The general idea is that the program will traverse through all 500 decision trees and store at each node a growing motif based on how the tree was split and pruned. Once it gets to a leaf node we have found a partial or local motif which it will store into a data structure with information about how many peptides were classified at that leaf and how many were classified incorrectly. It uses this classified/misclassified counts to score the motif then order all the motifs and print out the toxic motifs with the highest scores. These represent the motifs which are most likely to be the most toxic in the proetin library

5. CLUSTER:

The clustering phase of the pipeline takes the results from the motif finder and does meta analysis on the motifs as well as clustering the original data based on those motifs. The motifs are treated as regular expressions and all peptides that match that regex will clustered together based on that motif, and this list of clustered data will be used to find consensus motifs later in the pipeline.

The metaanalysis performed at this step calculates the peptide coverage and motif accuracy of the motifs the motif finder found and also calcualtes chi squared test of independence on the counts of motifs to see if they statistically significantly fall into one of the classifications. This allows us to say that a motif is statistically toxic or antitoxic, etc.

Peptide coverage is a percent from 0 to 1, and represents what percentage of the peptides have at least one motif matching to them in the classified motif set. The closer the value is to one, the better the motifs are at capturing the data. Motif accuracy is what percentage of peptides matched by the classified motifs are actually of a matching class. There is usually a tradeoff between peptide coverage and motif accuracy, for instance the trivial regex '........' which would literally match everything would have a 1.0 peptide coverage, but since it matches everything it would have terrible motif accuracy- close to '.33'. On the other side a highly specialized toxic motif '.F.FY.RF' may have motif accuracy score of 1.0: every single motif that matches this regex is toxic. However, it will only have a peptide coverage score of 0.03: meaning only 3% of all toxic motifs are matched by this pattern.

We want a set of toxic motifs that maximizes both of these scores, so a set of motifs which will match ALL peptides (have good peptide coverage), and not match any antitoxic or neutral peptides (have good motif accuracy).

6. FIND CONSENSUS MOTIFS:

7. TEST SIGNIFICANCE:


USAGE:

To run the pep-seq pipeline execute the run.sh script while in the pep-seq-pipeline main directory:

./run.sh [input_file_name] [-options]

OPTIONS:

--arff: data already in arff format, don not convert data
--anti: also find antitoxic motifs 
--neutral: also find neutral motifs 
--help: print usage 
-b: balance the data before running machine learning classifier 
-k [number_of_motifs]: specify the number of motifs to find 
-o [out_dir]: specify directy in results/ to save output files 

OUTPUT:

The pep-seq pipeline either prints ouput directly to the screen or saves output files in a directory in the result folder if the -o option is specific as a command parameter.

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