comparison cfsan_bettercallsal.xml @ 0:a4b1ee4b68b1

"planemo upload"
author kkonganti
date Mon, 05 Jun 2023 16:17:23 -0400
parents
children 365849f031fd
comparison
equal deleted inserted replaced
-1:000000000000 0:a4b1ee4b68b1
1 <tool id="cfsan_centriflaken" name="Centriflaken" version="0.2.0+galaxy0">
2 <description>An automated pipeline to generate a MAG of interest (E.coli or Salmonella) and perform serotyping.</description>
3 <requirements>
4 <requirement type="package" version="22.04">nextflow</requirement>
5 <requirement type="package">graphviz</requirement>
6 </requirements>
7 <version_command>nextflow -version</version_command>
8 <command detect_errors="exit_code"><![CDATA[
9 mkdir -p cpipes-input || exit 1;
10 pwd_path=\$(pwd);
11 #import re
12 #if (str($input_read_type_cond.input_read_type) == "single_long"):
13 #for _, $unpaired in enumerate($input_read_type_cond.input):
14 #set read1 = str($unpaired.name)
15 #if not str($unpaired.name).endswith(('.fastq', '.fastq.gz')):
16 #set read1_ext = re.sub('fastqsanger', 'fastq', str($unpaired.ext))
17 #set read1 = str($unpaired.name) + str('.') + $read1_ext
18 #end if
19 ln -sf '$unpaired' './cpipes-input/$read1';
20 #end for
21 #elif (str($input_read_type_cond.input_read_type) == "paired"):
22 #for _, $pair in enumerate($input_read_type_cond.input_pair)
23 #set read_R1 = re.sub('\:forward', '_forward', str($pair.forward.name))
24 #set read_R2 = re.sub('\:reverse', '_reverse', str($pair.reverse.name))
25 #set read_R1_ext = re.sub('fastqsanger', 'fastq', str($pair.forward.ext))
26 #set read_R2_ext = re.sub('fastqsanger', 'fastq', str($pair.reverse.ext))
27 #if not str($pair.forward.name).endswith(('.fastq', '.fastq.gz')):
28 #set read_R1 = $read_R1 + str('.') + $read_R1_ext
29 #end if
30 #if not str($pair.reverse.name).endswith(('.fastq', '.fastq.gz')):
31 #set read_R2 = $read_R2 + str('.') + $read_R2_ext
32 #end if
33 ln -sf '$pair.forward' './cpipes-input/$read_R1';
34 ln -sf '$pair.reverse' './cpipes-input/$read_R2';
35 #end for
36 #end if
37 $__tool_directory__/0.4.0/cpipes
38 --pipeline $input_read_type_cond.pipeline_cond.pipeline
39 #if ($input_read_type_cond.pipeline_cond.pipeline == "centriflaken"):
40 --fq_single_end true
41 --flye_genome_size '${genome_size}'
42 #if ($input_read_type_cond.pipeline_cond.long_read_platform == "nanopore_corr"):
43 --flye_nano_corr true --flye_nano_raw false
44 #elif ($input_read_type_cond.pipeline_cond.long_read_platform == "nanopore_hq"):
45 --flye_nano_hq true --flye_nano_raw false
46 #elif ($input_read_type_cond.pipeline_cond.long_read_platform == "pacbio_raw"):
47 --flye_pacbio_raw true --flye_nano_raw false
48 #elif ($input_read_type_cond.pipeline_cond.long_read_platform == "pacbio_corr"):
49 --flye_pacbio_corr true --flye_nano_raw false
50 #elif ($input_read_type_cond.pipeline_cond.long_read_platform == "pacbio_hifi"):
51 --flye_pacbio_hifi true --flye_nano_raw false
52 #end if
53 #elif ($input_read_type_cond.pipeline_cond.pipeline == "centriflaken_hy"):
54 #if (str($input_read_type_cond.input_read_type) == "single_long"):
55 --fq_single_end true
56 #elif (str($input_read_type_cond.input_read_type) == "paired"):
57 --fq_single_end false --fq2_suffix '${input_read_type_cond.fq2_suffix}'
58 #end if
59 #end if
60 --input \${pwd_path}/cpipes-input
61 --output \${pwd_path}/cpipes-output
62 --fq_suffix '${input_read_type_cond.fq_suffix}'
63 #if ($fq_filter_by_len != ""):
64 --fq_filter_by_len $fq_filter_by_len
65 #end if
66 --fq_filename_delim '${fq_filename_delim}'
67 --fq_filename_delim_idx $fq_filename_delim_idx
68 --centrifuge_extract_bug '${centrifuge_extract_bug}'
69 #if (str($input_read_type_cond.pipeline_cond.rm_dup_seqs) == "true"):
70 --seqkit_rmdup_run true
71 #end if
72 -profile kondagac;
73 mv './cpipes-output/${input_read_type_cond.pipeline_cond.pipeline}-multiqc/multiqc_report.html' './multiqc_report.html' > /dev/null 2>&1 || exit 1;
74 mv './cpipes-output/${input_read_type_cond.pipeline_cond.pipeline}-results/kraken2_extract_contigs' kraken2_extract_contigs > /dev/null 2>&1 || exit 1;
75 rm -rf ./cpipes-output > /dev/null 2>&1 || exit 1;
76 rm -rf ./work > /dev/null 2>&1 || exit 1
77 ]]></command>
78 <inputs>
79 <conditional name="input_read_type_cond">
80 <param name="input_read_type" type="select" label="Select the read collection type">
81 <option value="single_long" selected="true">Unpaired reads (i.e. Single-End short reads or Long reads)</option>
82 <option value="paired">Paired-End reads</option>
83 </param>
84 <when value="single_long">
85 <param name="input" type="data_collection" collection_type="list" format="fastq,fastq.gz"
86 label="Dataset list of unpaired short reads or long reads" />
87 <conditional name="pipeline_cond">
88 <param name="pipeline" type="select" label="CPIPES Workflow name"
89 help="centriflaken: for long reads (Nanopore or PacBio). centriflaken_hy: for unpaired short reads. Default: centriflaken">
90 <option value="centriflaken" selected="true">centriflaken</option>
91 <option value="centriflaken_hy">centriflaken_hy</option>
92 </param>
93 <when value="centriflaken">
94 <param name="long_read_platform" type="select" label="Mention long read sequencing platform and type">
95 <option value="nanopore_raw" selected="true">Nanopore raw reads, pre-Guppy5 (&lt;20% error)</option>
96 <option value="nanopore_corr">Nanopore reads that were corrected with other methods (&lt;3% error)</option>
97 <option value="nanopore_hq">Nanopore high-quality reads, Guppy5+ SUP or Q20 (5% error)</option>
98 <option value="pacbio_raw">PacBio regular CLR reads (&lt;20% error)</option>
99 <option value="pacbio_corr">PacBio reads that were corrected with other methods (&lt;3% error)</option>
100 <option value="pacbio_hifi">PacBio HiFi reads (&lt;1% error)</option>
101 </param>
102 <param name="rm_dup_seqs" type="select" label="Remove duplicate sequences"
103 help="THIS OPTION IS IGNORED IF THE INPUT READS ARE LONG READS.">
104 <option value="NA" selected="true">N/A</option>
105 </param>
106 </when>
107 <when value="centriflaken_hy">
108 <param name="long_read_platform" type="select" label="Mention long read sequencing platform and type"
109 help="THIS OPTION IS IGNORED IF THE INPUT READS ARE SHORT READS.">
110 <option value="NA" selected="true">N/A</option>
111 </param>
112 <param name="rm_dup_seqs" type="select" label="Remove duplicate sequences"
113 help="Selecting yes will compare sequence content and remove identical sequences i.e. only the first occured sequence record will be saved.">
114 <option value="true">yes</option>
115 <option value="false" selected="true">no</option>
116 </param>
117 </when>
118 </conditional>
119 <param name="fq_suffix" value=".fastq.gz" type="text" label="Suffix of the Unpaired FASTQ"/>
120 </when>
121 <when value="paired">
122 <param name="input_pair" type="data_collection" collection_type="list:paired" format="fastq,fastq.gz" label="List of Dataset pairs" />
123 <conditional name="pipeline_cond">
124 <param name="pipeline" type="select" label="CPIPES Workflow name"
125 help="Auto selected centriflaken_hy workflow for paired-end short reads.">
126 <option value="centriflaken_hy" selected="true">centriflaken_hy</option>
127 </param>
128 <when value="centriflaken_hy">
129 <param name="long_read_platform" type="select" label="Mention long read sequencing platform and type"
130 help="THIS OPTION IS IGNORED IF THE INPUT READS ARE SHORT READS.">
131 <option value="NA" selected="true">N/A</option>
132 </param>
133 <param name="rm_dup_seqs" type="select" label="Remove duplicate sequences"
134 help="Selecting yes will compare sequence content and remove identical sequences i.e. only the first occured sequence record will be saved.">
135 <option value="true">yes</option>
136 <option value="false" selected="true">no</option>
137 </param>
138 </when>
139 </conditional>
140 <param name="fq_suffix" value="_R1_001.fastq.gz" type="text" label="Suffix of the R1 FASTQ"/>
141 <param name="fq2_suffix" value="_R2_001.fastq.gz" type="text" label="Suffix of the R2 FASTQ"/>
142 </when>
143 </conditional>
144 <param name="fq_filter_by_len" optional="true" value="" type="integer" label="Enter minimum read length to retain before starting the analysis"
145 help="Keep this option empty to use default values. Default for centriflaken (long reads) is 4000 bp and for centriflaken_hy (short reads) is 75 bp."/>
146 <param name="fq_filename_delim" type="text" value="_" label="File name delimitor by which samples are grouped together (--fq_filename_delim)"
147 help="This is the delimitor by which samples are grouped together to display in the final MultiQC report. For example, if your input data sets are mango_replicate1.fastq.gz, mango_replicate2.fastq.gz, orange_replicate1_maryland.fastq.gz, orange_replicate2_maryland.fastq.gz, then to create 2 samples mango and orange, the value for --fq_filename_delim would be _ (underscore) and the value for --fq_filename_delim_idx would be 1, since you want to group by the first word (i.e. mango or orange) after splitting the filename based on _ (underscore)."/>
148 <param name="fq_filename_delim_idx" type="integer" value="1" label="File name delimitor index (--fq_filename_delim_idx)" />
149 <param name="centrifuge_extract_bug" type="text" value="Escherichia coli" label="Reads belonging to this taxa are extracted and a MAG is generated to allow for serotyping"/>
150 <param name="genome_size" type="text" optional="true" value="5.5m" label="Estimated genome size" help="For example, 5m or 2.6g.">
151 <validator type="regex" message="Genome size must be a float or integer, optionally followed by the a unit prefix (kmg)">^([0-9]*[.])?[0-9]+[kmg]?$</validator>
152 </param>
153 <!-- <param name="runtime_profile" type="select" label="Run time profile">
154 <option value="kondagac" selected="true">conda</option>
155 <option value="cingularitygac">singularity</option>
156 </param> -->
157 </inputs>
158 <outputs>
159 <data name="multiqc_report" format="html" label="${input_read_type_cond.pipeline_cond.pipeline}: MultiQC Report on ${on_string}" from_work_dir="multiqc_report.html"/>
160 <collection name="assembled_mags" type="list" label="${input_read_type_cond.pipeline_cond.pipeline}: Assembled MAGs on ${on_string}">
161 <discover_datasets pattern="(?P&lt;name&gt;.*)\.assembly_filtered_contigs\.fasta" ext="fasta" directory="kraken2_extract_contigs"/>
162 </collection>
163 </outputs>
164 <tests>
165 <!--Test 01: long reads-->
166 <test expect_num_outputs="2">
167 <param name="input">
168 <collection type="list">
169 <element name="FAL11127.fastq.gz" value="FAL11127.fastq.gz" />
170 <element name="FAL11341.fastq.gz" value="FAL11341.fastq.gz" />
171 <element name="FAL11342.fastq.gz" value="FAL11342.fastq.gz" />
172 </collection>
173 </param>
174 <param name="fq_suffix" value=".fastq.gz"/>
175 <output name="multiqc_report" file="multiqc_report.html" ftype="html" compare="sim_size"/>
176 <!-- <output name="assembled_mags" file="FAL11127.assembly_filtered.contigs.fasta" ftype="fasta" compare="sim_size"/> -->
177 </test>
178 </tests>
179 <help><![CDATA[
180
181 .. class:: infomark
182
183 **Purpose**
184
185 Centriflaken suite of automated data analysis pipelines are based on Nextflow DSL2 developed at CFSAN, FDA. These pipelines allow rapid
186 and effective construction of metagenomic assembled genomes (MAGs) to enable bacterial source-tracking. It is based on methods described in our
187 previous publication (Maguire *et al*, 2021. doi: https://doi.org/10.1371/journal.pone.0245172).
188
189 ----
190
191 .. class:: infomark
192
193 **Testing and Validation**
194
195 The CPIPES - Centriflaken Nextflow pipeline has been wrapped to make it work in Galaxy. It takes in either paired or unpaired short reads or long reads, generates MAGs and performs
196 in silico-based analysis (i.e., virulence gene finding). Additionally, AMR gene finding analysis is also included in Centriflaken and performed on MAGs
197 of interest. The final summary plots and tables can be downloaded from the provided MultiQC HTML report generated as part of the pipeline.
198 The Centriflaken pipeline was validated with data from our previously published method (Maguire *et al*, 2021. doi: https://doi.org/10.1371/journal.pone.0245172) and was able to replicate the detection
199 and classification of STECs for each sample. We tested the pipeline with Nanopore data obtained from 21 additional enriched samples from
200 irrigation water and was able to perform the entire precision metagenomics analysis in less than 5 hours for all of them. All the original testing and validation was
201 done on the command line on the CFSAN Raven2 HPC Cluster.
202
203
204 ----
205
206 .. class:: infomark
207
208 **Outputs**
209
210 The main output files are:
211
212 ::
213
214 - MultiQC Report: Contains a brief summary report including any serotyping and AMR result tables.
215 Please note that due to MultiQC customizations, the preview (eye icon) will not
216 work within Galaxy for the MultiQC report. Please download the file by clicking
217 on the floppy icon and view it in your browser on your local desktop/workstation.
218 - Final assembly: contains contigs and possibly scaffolds.
219
220 ]]></help>
221 <citations>
222 <citation type="bibtex">
223 @misc{gitlabCPIPES,
224 author = {Konganti, Kranti},
225 year = {2022},
226 title = {CPIPES - Centriflaken},
227 publisher = {GitLab},
228 journal = {GitLab repository},
229 url = {https://cfsan-git.fda.gov/Kranti.Konganti/cpipes}}
230 </citation>
231 </citations>
232 </tool>