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Genome Annotation using MAKER

*this tutorial is ever changing and was designed to annotate the horsefly genome, tabanid hinellus. *It has since been updated to be more general and work with varying levels of starting data. *This tutorial is designed to run in MPI mode.

Other tutorials and resources used to make this tutorial
https://darencard.net/blog/2017-05-16-maker-genome-annotation/
https://www.ncbi.nlm.nih.gov/genome/annotation_euk/process/
http://weatherby.genetics.utah.edu/MAKER/wiki/index.php/MAKER_Tutorial_for_WGS_Assembly_and_Annotation_Winter_School_2018
https://bioinformaticsworkbook.org/dataAnalysis/GenomeAnnotation/Intro_To_Maker.html#gsc.tab=0

Software & Data

Software prerequisites:

  1. RepeatModeler and RepeatMasker with all dependencies (I used NCBI BLAST) and RepBase (version used was 20150807).
  2. MAKER MPI version 2.31.8 (though any other version 2 releases should be okay).
  3. Augustus version 3.2.3.
  4. BUSCO version 2.0.1.
  5. SNAP version 2006-07-28.
  6. BEDtools version 2.17.0.
MY_GENOME=genome_assembly.fasta # ideally you have removed contamination from this assembly and don't have a lot of small contigs.
MY_TRANSCRIPTOME=transcriptome_assembly.fasta # optional but recommended, also called EST in this tutorial
MY_PROTEINS=proteome.fasta # Try uniprot_sprot.fasta

Setup Step 1: Train gene models with BUSCO --long option, this will be used later

lineage=aves_odb10
species=chicken
sample=
busco -l $lineage -m genome --augustus_species $species  -c 24 -i $GENOME -o busco-$species-$sample --long

Setup Step 2. De Novo Repeat Identification

The first, and very important, step to genome annotation is identifying repetitive content. Existing libraries from Repbase or from internal efforts are great, but it is also important to identify repeats de novo from your reference genome using RepeatModeler. This is pretty easy to do and normally only takes a couple days using 8-12 cores.

http://weatherby.genetics.utah.edu/MAKER/wiki/index.php/Repeat_Library_Construction--Basic

http://www.repeatmasker.org/RepeatModeler/

BuildDatabase -name genome_db -engine $MY_GENOME

RepeatModeler -pa 32 #number of cores \
-engine ncbi #optional, as ncbi is the default engine \
-database genome_db 2>&1 | tee repeatmodeler.log

The output from this that we will use is called consensi.fa.classified

Download RepBase data for close relative and concatenate with tabanid repeat model.

RepBase - https://www.girinst.org/server/RepBase/index.php # you need a subscription now. NOT COOL.

Full Repeat Annotation (optional)

Depending on the species, the de novo library can be fed right into MAKER. Here we do more complex repeat identification.

mkdir repeatMasker-tabanid_model

RepeatMasker -pa 24 #number of cores /
-e ncbi #engine /
-gccalc #calculate GC content /
-lib combined-conseni.fa.classified #concatenated consensi.fa.classified and RepBase files \
-dir repeatMasker-model #output directory \
 $MY_GENOME #assembly file

Then the masked FASTA from this search can be used as input for the next search, using the arthropoda library from Repbase.

mkdir repeatMasker-output

# The below command needs to be adjusted
repeat_species=arthropoda

RepeatMasker -pa 24 \
-e ncbi \
-gccalc \
-a #creates an alignment files that cab be used with jbrowse \
-s #slow search (more sensitive, but slower)
-species $repeat_species #species name must be in the NCBI Taxonomy Database\
-dir repeatMasker-output #output directory\
$MY_GENOME #assembly file

Combine all data to produce the final repeat annotations

mkdir full_mask
gunzip repeatMasker-output/*.cat.gz 
cat repeatMasker-output/*.cat.gz> full_mask/full_mask.cat
cd full_mask
ProcessRepeats -species arthropoda full_mask.cat

In order to feed these repeats into MAKER properly, we must separate out the complex repeats (more info on this below).

# create GFF3
rmOutToGFF3.pl full_mask/full_mask.out > full_mask/full_mask.out.gff3
# isolate complex repeats
grep -v -e "Satellite" -e ")n" -e "-rich" full_mask.out.gff3 \
  > full_mask.out.complex.gff3
# reformat to work with MAKER
cat full_mask.out.complex.gff3 | \
  perl -ane '$id; if(!/^\#/){@F = split(/\t/, $_); chomp $F[-1];$id++; $F[-1] .= "\;ID=$id"; $_ = join("\t", @F)."\n"} print $_' \
  > full_mask.out.complex.reformat.gff3

Now we have the prerequesite data for running MAKER.

complex_repeats=full_mask.out.complex.reformat.gff3
# note: maker will do the simple repeats

Initial MAKER Analysis

MAKER is pretty easy to get going and relies on properly completed control files. These can be generated by issuing the command maker -CTL. The only control file we will be the maker_opts.ctl file. In this first round, we will obviously providing the data files for the repeat annotation (rm_gff), the transcriptome assembly (est), and for the other Squamate protein sequences (protein). We will also set the model_org to 'simple' so that only simple repeats are annotated (along with RepeatRunner). Here is the full control file for reference.

maker -OPTS && maker -BOPTS && maker -EXE

Edit OPTS files with starting data

#add genome variable THESE COMMANDS DO NOT WORK WITH ABSOLUE PATHS, JUST MANUALLY EDIT THEM
sed -i 's/'^genome='/'genome="$MY_GENOME"'/g' maker_opts.ctl
#add transcriptome to est line
sed -i 's/'^est='/'est="$my_transcriptome"'/g' maker_opts.ctl
#add protein evidence  (use swissprot or a set from a closely related species fi yoou have them)
protein=$MY_PROTEINS
cat round1_maker_opts.ctl

#-----Genome (these are always required)
genome=*ABSOLUTE_PATH_TO_GENOME* #genome sequence (fasta file or fasta embeded in GFF3 file)
organism_type=eukaryotic #eukaryotic or prokaryotic. Default is eukaryotic

#-----Re-annotation Using MAKER Derived GFF3
maker_gff= #MAKER derived GFF3 file
est_pass=0 #use ESTs in maker_gff: 1 = yes, 0 = no
altest_pass=0 #use alternate organism ESTs in maker_gff: 1 = yes, 0 = no
protein_pass=0 #use protein alignments in maker_gff: 1 = yes, 0 = no
rm_pass=0 #use repeats in maker_gff: 1 = yes, 0 = no
model_pass=0 #use gene models in maker_gff: 1 = yes, 0 = no
pred_pass=0 #use ab-initio predictions in maker_gff: 1 = yes, 0 = no
other_pass=0 #passthrough anyything else in maker_gff: 1 = yes, 0 = no

#-----EST Evidence (for best results provide a file for at least one)
est=*ABSOLUTE_PATH_TO_TRANSCRIPTOME* #set of ESTs or assembled mRNA-seq in fasta format
altest= #EST/cDNA sequence file in fasta format from an alternate organism
est_gff= #aligned ESTs or mRNA-seq from an external GFF3 file
altest_gff= #aligned ESTs from a closly relate species in GFF3 format

#-----Protein Homology Evidence (for best results provide a file for at least one)
protein=*ABSOLUTE_PATH_TO_PROTEINS* #protein sequence file in fasta format (i.e. from mutiple oransisms)
protein_gff=  #aligned protein homology evidence from an external GFF3 file

#-----Repeat Masking (leave values blank to skip repeat masking)
model_org=simple #select a model organism for RepBase masking in RepeatMasker
rmlib= #provide an organism specific repeat library in fasta format for RepeatMasker
repeat_protein=/opt/maker/data/te_proteins.fasta #provide a fasta file of transposable element proteins for RepeatRunner
rm_gff=/home/castoelab/Desktop/daren/boa_annotation/Full_mask/Boa_constrictor_SGA_7C_scaffolds.full_mask.complex.reformat.gff3 #pre-identified repeat elements from an external GFF3 file
prok_rm=0 #forces MAKER to repeatmask prokaryotes (no reason to change this), 1 = yes, 0 = no
softmask=1 #use soft-masking rather than hard-masking in BLAST (i.e. seg and dust filtering)

#-----Gene Prediction
snaphmm= #SNAP HMM file
gmhmm= #GeneMark HMM file
augustus_species= #Augustus gene prediction species model
fgenesh_par_file= #FGENESH parameter file
pred_gff= #ab-initio predictions from an external GFF3 file
model_gff= #annotated gene models from an external GFF3 file (annotation pass-through)
est2genome=1 #infer gene predictions directly from ESTs, 1 = yes, 0 = no
protein2genome=1 #infer predictions from protein homology, 1 = yes, 0 = no
trna=0 #find tRNAs with tRNAscan, 1 = yes, 0 = no
snoscan_rrna= #rRNA file to have Snoscan find snoRNAs
unmask=0 #also run ab-initio prediction programs on unmasked sequence, 1 = yes, 0 = no

#-----Other Annotation Feature Types (features MAKER doesn't recognize)
other_gff= #extra features to pass-through to final MAKER generated GFF3 file

#-----External Application Behavior Options
alt_peptide=C #amino acid used to replace non-standard amino acids in BLAST databases
cpus=1 #max number of cpus to use in BLAST and RepeatMasker (not for MPI, leave 1 when using MPI)

#-----MAKER Behavior Options
max_dna_len=100000 #length for dividing up contigs into chunks (increases/decreases memory usage)
min_contig=1 #skip genome contigs below this length (under 10kb are often useless)

pred_flank=200 #flank for extending evidence clusters sent to gene predictors
pred_stats=0 #report AED and QI statistics for all predictions as well as models
AED_threshold=1 #Maximum Annotation Edit Distance allowed (bound by 0 and 1)
min_protein=0 #require at least this many amino acids in predicted proteins
alt_splice=0 #Take extra steps to try and find alternative splicing, 1 = yes, 0 = no
always_complete=0 #extra steps to force start and stop codons, 1 = yes, 0 = no
map_forward=0 #map names and attributes forward from old GFF3 genes, 1 = yes, 0 = no
keep_preds=0 #Concordance threshold to add unsupported gene prediction (bound by 0 and 1)

split_hit=10000 #length for the splitting of hits (expected max intron size for evidence alignments)
single_exon=0 #consider single exon EST evidence when generating annotations, 1 = yes, 0 = no
single_length=250 #min length required for single exon ESTs if 'single_exon is enabled'
correct_est_fusion=0 #limits use of ESTs in annotation to avoid fusion genes

tries=2 #number of times to try a contig if there is a failure for some reason
clean_try=0 #remove all data from previous run before retrying, 1 = yes, 0 = no
clean_up=0 #removes theVoid directory with individual analysis files, 1 = yes, 0 = no
TMP= #specify a directory other than the system default temporary directory for temporary files

Specifying the GFF3 annotation file for the annotated complex repeats (rm_gff) has the effect of hard masking these repeats so that they do not confound our ability to identify coding genes. We let MAKER identify simple repeats internally, since it will soft mask these, allowing them to be available for gene annotation. This isn't a typical approach but has to be done if you want to do more than one succeessive round of RepeatMasker. I verified this would work with the MAKER maintainers here.

Two other important settings are est2genome and protein2genome, which are set to 1 so that MAKER gene predictions are based on the aligned transcripts and proteins (the only form of evidence we currently have). I also construct the MAKER command in a Bash script so it is easy to run and keep track of.

cat round1_run_maker.sh
mpiexec -n 12 maker -base maker_rnd1 round1_maker_opts.ctl maker_bopts.ctl maker_exe.ctl

Then we run MAKER.

bash ./round1_run_maker.sh 2>&1 | tee round1_run_maker.log

Given MAKER will be using BLAST to align transcripts and proteins to the genome, this will take at least a couple days with 12 cores. Speed is a product of the resources you allow (more cores == faster) and the assembly quality (smaller, less contiguous scaffolds == longer). We conclude by assembling together the GFF and FASTA outputs.

cd Bcon_rnd1.maker.output
gff3_merge -s -d Bcon_rnd1_master_datastore_index.log > Bcon_rnd1.all.maker.gff
fasta_merge -d Bcon_rnd1_master_datastore_index.log
# GFF w/o the sequences
gff3_merge -n -s -d Bcon_rnd1_master_datastore_index.log > Bcon_rnd1.all.maker.noseq.gff

4. Training Gene Prediction Software

Besides mapping the empirical transcript and protein evidence to the reference genome and repeat annotation (not much of this in our example, given we've done so much up front), the most important product of this MAKER run is the gene models. These are what is used for training gene prediction software like augustus and snap.

SNAP

SNAP is pretty quick and easy to train. Issuing the following commands will perform the training. It is best to put some thought into what kind of gene models you use from MAKER. In this case, we use models with an AED of 0.25 or better and a length of 50 or more amino acids, which helps get rid of junky models.

mkdir snap
mkdir snap/round1
cd snap/round1
# export 'confident' gene models from MAKER and rename to something meaningful
maker2zff -x 0.25 -l 50 -d ../../Bcon_rnd1.maker.output/Bcon_rnd1_master_datastore_index.log
rename 's/genome/Bcon_rnd1.zff.length50_aed0.25/g' *
# gather some stats and validate
fathom Bcon_rnd1.zff.length50_aed0.25.ann Bcon_rnd1.zff.length50_aed0.25.dna -gene-stats > gene-stats.log 2>&1
fathom Bcon_rnd1.zff.length50_aed0.25.ann Bcon_rnd1.zff.length50_aed0.25.dna -validate > validate.log 2>&1
# collect the training sequences and annotations, plus 1000 surrounding bp for training
fathom Bcon_rnd1.zff.length50_aed0.25.ann Bcon_rnd1.zff.length50_aed0.25.dna -categorize 1000 > categorize.log 2>&1
fathom uni.ann uni.dna -export 1000 -plus > uni-plus.log 2>&1
# create the training parameters
mkdir params
cd params
forge ../export.ann ../export.dna > ../forge.log 2>&1
cd ..
# assembly the HMM
hmm-assembler.pl Bcon_rnd1.zff.length50_aed0.25 params > Bcon_rnd1.zff.length50_aed0.25.hmm
Augustus

Training Augustus is a more laborious process. Luckily, the recent release of BUSCO provides a nice pipeline for performing the training, while giving you an idea of how good your annotation already is. If you don't want to go this route, there are scripts provided with Augustus to perform the training. First, the Parallel::ForkManager module for Perl is required to run BUSCO with more than one core. You can easily install it before the first time you use BUSCO by running sudo apt-get install libparallel-forkmanager-perl.

This probably isn't an ideal training environment, but appears to work well. First, we must put together training sequences using the gene models we created in our first run of MAKER. We do this by issuing the following command to excise the regions that contain mRNA annotations based on our initial MAKER run (with 1000bp on each side).

awk -v OFS="\t" '{ if ($3 == "mRNA") print $1, $4, $5 }' ../../Bcon_rnd1.maker.output/Bcon_rnd1.all.maker.noseq.gff | \
  awk -v OFS="\t" '{ if ($2 < 1000) print $1, "0", $3+1000; else print $1, $2-1000, $3+1000 }' | \
  bedtools getfasta -fi ../../Boa_constrictor_SGA_7C_scaffolds.fa -bed - -fo Bcon_rnd1.all.maker.transcripts1000.fasta

There are some important things to note based on this approach. First is that you will likely get warnings from BEDtools that certain coordinates could not be used to extract FASTA sequences. This is because the end coordinate of a transcript plus 1000 bp is beyond the total length of a given scaffold. This script does account for transcripts being within the beginning 1000bp of the scaffold, but there was no easy way to do the same with transcrpts within the last 1000bp of the scaffold. This is okay, however, as we still end up with sequences from thousands of gene models and BUSCO will only be searching for a small subset of genes itself.

While we've only provided sequences from regions likely to contain genes, we've totally eliminated any existing annotation data about the starts/stops of gene elements. Augustus would normally use this as part of the training process. However, BUSCO will essentially do a reannotation of these regions using BLAST and built-in HMMs for a set of conserved genes (hundreds to thousands). This has the effect of recreating some version of our gene models for these conserved genes. We then leverage the internal training that BUSCO can perform (the --long argument) to optimize the HMM search model to train Augustus and produce a trained HMM for MAKER. Here is the command we use to perform the Augustus training inside BUSCO.

# See the beginning of the tutorial to run BUSCO

In this case, we are using a set of conserved genes which BUSCO will try to identify those gene using BLAST and an initial HMM model for each that comes stocked within BUSCO. We specify the -m genome option since we are giving BUSCO regions that include more than just transcripts. The initial HMM model we'll use is the human one (-sp human), which is a reasonably close species. Finally, the --long option tells BUSCO to use the initial gene models it creates to optimize the HMM settings of the raw human HMM, thus training it for our use on Boa. We can have this run in parallel on several cores, but it will still likely take days, so be patient.

Once BUSCO is complete, it will give you an idea of how complete your annotation is (though be cautious, because we haven't filtered away known alternative transcripts that will be binned as duplicates). We need to do some post-processing of the HMM models to get them ready for MAKER. First, we'll rename the files within run_Bcon_rnd1_maker/augustus_output/retraining_paramters.

rename 's/BUSCO_Bcon_rnd2_maker_2277442865/Boa_constrictor/g' *

We also need to rename the files cited within certain HMM configuration files.

sed -i 's/BUSCO_Bcon_rnd2_maker_2277442865/Boa_constrictor/g' Boa_constrictor_parameters.cfg
sed -i 's/BUSCO_Bcon_rnd2_maker_2277442865/Boa_constrictor/g' Boa_constrictor_parameters.cfg.orig1

Finally, we must copy these into the $AUGUSTUS_CONFIG_PATH species HMM location so they are accessible by Augustus and MAKER.

# may need to sudo
mkdir $AUGUSTUS_CONFIG_PATH/species/Boa_constrictor
cp Boa_constrictor*  $AUGUSTUS_CONFIG_PATH/species/Boa_constrictor/

5. MAKER With Ab Initio Gene Predictors

Now let's run a second round of MAKER, but this time we will have SNAP and Augustus run within MAKER to help create more sound gene models. MAKER will use the annotations from these two prediction programs when constructing its models. Before running, let's first recycle the mapping of empicial evidence we have from the first MAKER round, so we don't have to perform all the BLASTs, etc. again.

# transcript alignments
awk '{ if ($2 == "est2genome") print $0 }' Bcon_rnd1.all.maker.noseq.gff > Bcon_rnd1.all.maker.est2genome.gff
# protein alignments
awk '{ if ($2 == "protein2genome") print $0 }' Bcon_rnd1.all.maker.noseq.gff > Bcon_rnd1.all.maker.protein2genome.gff
# repeat alignments
awk '{ if ($2 ~ "repeat") print $0 }' Bcon_rnd1.all.maker.noseq.gff > Bcon_rnd1.all.maker.repeats.gff

Then we will modify the previous control file, removing the FASTA sequences files to map and replacing them with the GFFs (est_gff, protein_gff, and rm_gff, respectively. We can also specify the path to the SNAP HMM and the species name for Augustus, so that these gene prediciton programs are run. We will also switch est2genome and protein2genome to 0 so that gene predictions are based on the Augustus and SNAP gene models. Here is the full version of this control file.

cat round2_maker_opts.ctl

#-----Genome (these are always required)
genome=/home/castoelab/Desktop/daren/boa_annotation/Boa_constrictor_SGA_7C_scaffolds.fa #genome sequence (fasta file or fasta embeded in GFF3 file)
organism_type=eukaryotic #eukaryotic or prokaryotic. Default is eukaryotic

#-----Re-annotation Using MAKER Derived GFF3
maker_gff= #MAKER derived GFF3 file
est_pass=0 #use ESTs in maker_gff: 1 = yes, 0 = no
altest_pass=0 #use alternate organism ESTs in maker_gff: 1 = yes, 0 = no
protein_pass=0 #use protein alignments in maker_gff: 1 = yes, 0 = no
rm_pass=0 #use repeats in maker_gff: 1 = yes, 0 = no
model_pass=0 #use gene models in maker_gff: 1 = yes, 0 = no
pred_pass=0 #use ab-initio predictions in maker_gff: 1 = yes, 0 = no
other_pass=0 #passthrough anyything else in maker_gff: 1 = yes, 0 = no

#-----EST Evidence (for best results provide a file for at least one)
est= #set of ESTs or assembled mRNA-seq in fasta format
altest= #EST/cDNA sequence file in fasta format from an alternate organism
est_gff=/home/castoelab/Desktop/daren/boa_annotation/Bcon_rnd1.maker.output/Bcon_rnd1.all.maker.est2genome.gff #aligned ESTs or mRNA-seq from an external GFF3 file
altest_gff= #aligned ESTs from a closly relate species in GFF3 format

#-----Protein Homology Evidence (for best results provide a file for at least one)
protein= #protein sequence file in fasta format (i.e. from mutiple oransisms)
protein_gff=/home/castoelab/Desktop/daren/boa_annotation/Bcon_rnd1.maker.output/Bcon_rnd1.all.maker.protein2genome.gff  #aligned protein homology evidence from an external GFF3 file

#-----Repeat Masking (leave values blank to skip repeat masking)
model_org= #select a model organism for RepBase masking in RepeatMasker
rmlib= #provide an organism specific repeat library in fasta format for RepeatMasker
repeat_protein= #provide a fasta file of transposable element proteins for RepeatRunner
rm_gff=/home/castoelab/Desktop/daren/boa_annotation/Bcon_rnd1.maker.output/Bcon_rnd1.all.maker.repeats.gff #pre-identified repeat elements from an external GFF3 file
prok_rm=0 #forces MAKER to repeatmask prokaryotes (no reason to change this), 1 = yes, 0 = no
softmask=1 #use soft-masking rather than hard-masking in BLAST (i.e. seg and dust filtering)

#-----Gene Prediction
snaphmm=/home/castoelab/Desktop/daren/boa_annotation/snap/round1/Bcon_rnd1.zff.length50_aed0.25.hmm #SNAP HMM file
gmhmm= #GeneMark HMM file
augustus_species=Boa_constrictor #Augustus gene prediction species model
fgenesh_par_file= #FGENESH parameter file
pred_gff= #ab-initio predictions from an external GFF3 file
model_gff= #annotated gene models from an external GFF3 file (annotation pass-through)
est2genome=0 #infer gene predictions directly from ESTs, 1 = yes, 0 = no
protein2genome=0 #infer predictions from protein homology, 1 = yes, 0 = no
trna=1 #find tRNAs with tRNAscan, 1 = yes, 0 = no
snoscan_rrna= #rRNA file to have Snoscan find snoRNAs
unmask=0 #also run ab-initio prediction programs on unmasked sequence, 1 = yes, 0 = no

#-----Other Annotation Feature Types (features MAKER doesn't recognize)
other_gff= #extra features to pass-through to final MAKER generated GFF3 file

#-----External Application Behavior Options
alt_peptide=C #amino acid used to replace non-standard amino acids in BLAST databases
cpus=1 #max number of cpus to use in BLAST and RepeatMasker (not for MPI, leave 1 when using MPI)

#-----MAKER Behavior Options
max_dna_len=300000 #length for dividing up contigs into chunks (increases/decreases memory usage)
min_contig=1 #skip genome contigs below this length (under 10kb are often useless)

pred_flank=200 #flank for extending evidence clusters sent to gene predictors
pred_stats=0 #report AED and QI statistics for all predictions as well as models
AED_threshold=1 #Maximum Annotation Edit Distance allowed (bound by 0 and 1)
min_protein=0 #require at least this many amino acids in predicted proteins
alt_splice=0 #Take extra steps to try and find alternative splicing, 1 = yes, 0 = no
always_complete=0 #extra steps to force start and stop codons, 1 = yes, 0 = no
map_forward=0 #map names and attributes forward from old GFF3 genes, 1 = yes, 0 = no
keep_preds=0 #Concordance threshold to add unsupported gene prediction (bound by 0 and 1)

split_hit=20000 #length for the splitting of hits (expected max intron size for evidence alignments)
single_exon=0 #consider single exon EST evidence when generating annotations, 1 = yes, 0 = no
single_length=250 #min length required for single exon ESTs if 'single_exon is enabled'
correct_est_fusion=0 #limits use of ESTs in annotation to avoid fusion genes

tries=2 #number of times to try a contig if there is a failure for some reason
clean_try=0 #remove all data from previous run before retrying, 1 = yes, 0 = no
clean_up=0 #removes theVoid directory with individual analysis files, 1 = yes, 0 = no
TMP= #specify a directory other than the system default temporary directory for temporary files

Then we can run MAKER, substituting this new control file, and summarize the output, as we did before.

6. Iteratively Running MAKER to Improve Annotation

One of the beauties of MAKER is that it can be run iteratively, using the gene models from the one round to train ab initio software to improve the inference of gene models in the next round. Essentially, all one has to do is repeat steps 4 and 5 to perform another round of annotation. The MAKER creators/maintainers recommend at least a couple rounds of ab initio software training and MAKER annotation (i.e., 3 rounds total) and returns start to diminish (at differing rates) thereafter. One needs to be careful not to overtrain Augustus and SNAP, so more rounds isn't necessarily always better. Below are a few ways of evaluating your gene models after successive rounds of MAKER to identify when you have sound models.

A. Count the number of gene models and the gene lengths after each round.

cat <roundN.full.gff> | awk '{ if ($3 == "gene") print $0 }' | awk '{ sum += ($5 - $4) } END { print NR, sum / NR }'

B. Visualize the AED distribution. AED ranges from 0 to 1 and quantifies the confidence in a gene model based on empirical evidence. Basically, the lower the AED, the better a gene model is likely to be. Ideally, 95% or more of the gene models will have an AED of 0.5 or better in the case of good assemblies. You can use this AED_cdf_generator.pl script to help with this.

perl AED_cdf_generator.pl -b 0.025 <roundN.full.gff>

C. Run BUSCO one last time using the species Augustus HMM and take a look at the results (this will be quick since we are not training Augustus). Also, only include the transcript sequences (not the 1000 bp on each side) and be sure to take the best (i.e., longest) transcript for each gene so you aren't artificially seeding duplicates. You can also run it on the best protein sequence per gene instead. Your command will be some derivative of the following:

BUSCO.py -i <roundN.transcripts.fasta>  -o annotation_eval -l tetrapoda_odb9/ \
  -m transcriptome -c 8 -sp Boa_constrictor -z --augustus_parameters='--progress=true'

D. Visualize the gene models from Augustus, SNAP, and MAKER using a genome browser. JBrowse is a good option for this. You can essentially follow this guide to get this started. A helpful resource is this gff2jbrowse.pl script, which automates adding tracks to the browser based on the GFF output of your MAKER run. It is best to use 5-10 longer, gene dense scaffolds and visually inspect them. When SNAP and Augustus are well trained, their models should overlap pretty closely with the final MAKER models. Moreover, there will be spurious hits from SNAP and Augustus, but they are usually short, 1-2 exon annotations and don't have empirical support. You'll get a sense of a good annotation with some experience. Also, it is possible SNAP won't produce good results, depending on your organism, which the MAKER folks have pointed out in the past (Augustus usually does pretty well).

7. Downstream Processing and Homology Inference

After running MAKER one now has protein models, but that isn't all together very useful. First, the MAKER default names are long, ugly, and likely difficult for programs to parse. Moreover, even if they were named "gene1", etc. that doesn't tell you anything about what the genes actually are. Therefore, it is necessary to do some downstream processing of the MAKER output and to use homology searches against existing databases to annotate more functional information about genes.

A. First, let's rename the IDs that MAKER sets by default for genes and transcripts. MAKER comes with some scripts to do just this and to swap them out in the GFF and FASTA output (instructions for generated are above). The commands below first create custom IDs and store them as a table, and then use that table to rename the original GFF and FASTA files (they are overwritten, but it is possible to regenerate the raw ones again).

# create naming table (there are additional options for naming beyond defaults)
maker_map_ids --prefix BoaCon --justify 5  Bcon_rnd3.all.maker.gff > Bcon_rnd3.all.maker.name.map
# replace names in GFF files
map_gff_ids Bcon_rnd3.all.maker.name.map Bcon_rnd3.all.maker.gff
map_gff_ids Bcon_rnd3.all.maker.name.map Bcon_rnd3.all.maker.noseq.gff
# replace names in FASTA headers
map_fasta_ids Bcon_rnd3.all.maker.name.map Bcon_rnd3.all.maker.transcripts.fasta
map_fasta_ids Bcon_rnd3.all.maker.name.map Bcon_rnd3.all.maker.proteins.fasta

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Construct ab initio gene prediction using only BUSCO augustus models. Add in transcriptome for extra support

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